KR20070051346A - Data communication system, receiver apparatus and transmitter apparatus - Google Patents

Abstract

In a wireless communication system based on the OFDM technology, it is possible to multiplex the control channel and the low speed data channel without reducing the transmission speed of the traffic channel. In a communication system operating by multiplexing a traffic channel for performing high-speed data transmission and a control channel for transmitting low-speed control information, an OFDM signal for transmitting a traffic channel and an OFDM signal for transmitting a control signal are multiplexed and transmitted. The receiving station first demodulates and decodes the control channel to determine whether the signal of the traffic channel is sent to the station. If the one sent to the local station is included, the control channel signal is canceled from the received signal according to the quality of the radio communication path, and the traffic channel is demodulated.

OFDM, traffic channel, control channel, multiplexing, demodulation, replication

Description

DATA COMMUNICATION SYSTEM, RECEIVER APPARATUS AND TRANSMITTER APPARATUS}

TECHNICAL FIELD The present invention relates to a data communication system, a reception apparatus, and a transmission apparatus, and more particularly, to a data communication system using OFDM technology.

The demand for wireless data communication systems using radio waves, such as wireless LANs and cellular telephone systems, has been increasing. A technique for realizing high-speed data communication using limited frequency resources is desired.

Orthogonal Frequency Division Multiplexing (OFDM) technology is a technology used for broadband wireless communication including IEEE802.11g and 802.11a for realizing high-speed wireless LAN.

Orthogonal Frequency and Code Division Multiplexing (OFCDM) and Multi-Carrier Code Division Multiple Access (MC-CDMA) schemes adopt the idea of spectral spreading and code division multiplexing based on OFDM technology. The expression MC-CDMA is also used in a system for communicating by using a plurality of narrowband CDMA signals in parallel, but is limited to those based on OFDM technology. In addition, MC-CDMA based on OFDM technology is considered to be included in OFCDM, and the following expression, OFCDM, is used. Hereinafter, OFDM and OFCDM will be briefly described.

41 shows a block diagram of OFDM. The number of transmission symbols in one frame is referred to as Nf = Ns x Nc. Nc is the number of subcarriers, Ns is the number of OFDM symbols. In addition to this, a pilot symbol for channel (wireless communication channel) estimation is usually included but is omitted here.

In the transmitter of FIG. 41A, the transmission symbols parallelized for each Nc symbol by the S / P conversion (serial and parallel conversion) 101 become respective subcarrier components, and IFFT (inverse fast Fourier transform) processing 102 ), And P / S conversion (parallel and serial conversion) 103 is performed to form a time signal sequence. Here, the processing unit of the FFT (fast Fourier transform) is one symbol of OFDM. In Add GI 104, a GI (guard interval) is added for each OFDM symbol. The guard interval is to insert a signal behind the OFDM symbol before the OFDM symbol, as shown in FIG. By this guard interval, interference by delay waves in the wireless communication path can be suppressed.

43 shows the arrangement of transmission symbols in a transmission signal within one frame. In this example, one frame is composed of Ns OFDM symbols, and transmission symbols are sequentially arranged in the frequency direction among the OFDM symbols.

In the receiver of FIG. 41B, in the Remove GI 106, the OFDM symbol, that is, the FFT unit is cut out according to the detection result by the timing detection 105, and the S / P conversion 107 is performed. Processing 108 is performed to extract each subcarrier component. Thereafter, P / S conversion 109 is performed to obtain symbol strings in the same procedure as the symbol arrangement of the transmission frame.

In OFCDM, by spreading in the frequency domain or the time domain, the same transmission symbol is arranged over a plurality of subcarriers or a plurality of OFDM symbols as shown in FIG. In FIG. 44A, the spreading ratio of the frequency domain is 4, and the same data symbol is transmitted by four subcarriers. In FIG. 44B, the spreading ratios of the frequency domain and the time domain are both two, and the same data symbol is transmitted by two subcarriers and two OFDM symbols. In these examples, since the spreading factor 4 is spread, the transmission symbol transmission rate is 1/4. This is an idea of spread spectrum, and signal power density can be lowered by transmitting a signal using more frequency bands or time slots than frequency bands or time slots necessary for transmission symbol transmission. In addition, by using a wide frequency range, a frequency diversity effect can be obtained. In addition, by multiplying orthogonal codes by spreading codes at the time of spreading, it is possible to multiplex and transmit different transmission symbols using the same area. This is the idea of code division multiplexing. By code division multiplexing, it is possible to increase the transmission rate, thereby enabling control of the transmission rate corresponding to the communication path environment.

45 is a block diagram showing a transmitter and a receiver of a general OFCDM, in which a transmitter is shown in FIG. 45A and a receiver is shown in FIG. 45B.

In the transmitter, the spreading ratio of the frequency domain spreading is set to SF. The number of transmission symbols in one frame is 1 / SF compared to OFDM. The symbols parallelized for each Nc / SF symbol in the S / P conversion 111 are subjected to spreading processing in the frequency domain, thereby forming respective subcarrier components. In the frequency domain spreading process 112, one symbol is copied into SF subcarrier components, and spread symbols {C ₀ , C ₁ ,... C _{SF -1} } is multiplied. Here, a complex numerical sequence of code length SF is used as a spread code. In addition, IFFT processing 113 and P / S conversion 114 are performed to form a time signal string. In the Add GI 115, a GI (guard interval) is added for each OFDM symbol.

In the receiver of FIG. 45B, in the timing detection / channel estimation process 116, timing detection channel estimation is performed to obtain a timing for cutting out a received signal for performing the FFT process and a channel estimation value. From this channel estimate, the weighting coefficient multiplied by each subcarrier after FFT is determined.

The guard interval is removed by the Remove GI 117, and the received signal is demodulated. Since the control channel is subjected to OFCDM modulation for frequency domain spreading, the despreading process is performed using the complex conjugate of the spreading code used for spreading and the weighting coefficient obtained from the channel estimating section. There are various methods of determining the weighting coefficient, but here the channel coefficients {W ₀ , W ₁ ,..., Corresponding to each subcarrier are used. The complex conjugate of W _{N -1} } is used. Here, S / P conversion 118, FFT processing 119, frequency domain despreading 120, and P / S conversion 121 are executed.

In the next generation cellular mobile communication system, the OFDM-based SCS-MC-CDMA system (Non-Patent Document 1) and the similarly OFDM-based VSF-OFCDM system (Non-Patent Document 2) have been studied. The SCS-MC-CDMA scheme arranges control channels and communication channels on different subcarriers on the frequency axis. On the other hand, the VSF-OFCDM method is a method of multiplexing a data channel spread in a time domain and a control channel spread in both a time frequency region using an orthogonal code.

Patent Document 1 is an invention related to OFDM and MC-CDMA. This means that in a cellular mobile communication system, whether to use OFDM or MC-CDMA is switched in units of transmission slots according to the communication path state between the mobile terminal and the base station.

Patent Document 1: Japanese Patent Application Laid-Open No. 2004-158901

Non-Patent Document 1: Hwa et al., "A Review of Common Control Channel Synchronization in the SCS-MC-CDMA System," 2004, 2004.

[Non-Patent Literature 2] Miyama et al., "Outdoor Experiment Results of Adaptive Modulation / Decoding / Channel Coding in Downlink VSF-OFCDM Broadband Radio Access," 2004. B-5-94

Problems to be Solved by the Invention

The above-described SCS-MC-CDMA allocates a part of a plurality of subcarriers used in OFDM as a control channel. In this case, a problem arises such that a specific subcarrier cannot be used for data transmission, and a frequency diversity effect becomes difficult to be obtained. In addition, in VSF-OFCDM, the number of code multiplexes is limited to the amount assigned to the control channel. Also, since the code must be allocated so that the control channel and the traffic channel do not interfere, the freedom of radio parameters such as spreading rate is lowered. do. It is also conceivable to assign a specific symbol in a frame as a control channel, but there is also a problem of lowering the transmission speed and lowering the degree of freedom of radio parameters.

For example, when the spreading rate of the traffic channel is 8, even if the control channel is low and the spreading rate corresponding to the required transmission rate is 128, only 7 codes can be assigned to the traffic channel, and the transmission rate is lowered.

The same problem as these occurs even when the continuous low data channel and the non-contiguous high data channel are multiplexed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described circumstances, and solves the problems related to multiplexing a traffic channel that enables high-speed data transmission and a control channel that transmits low-speed control signals in a next generation cellular mobile communication system. It is intended to be.

Another object of the present invention is to solve a problem relating to multiplexing of traffic channel 1 for high speed data transmission and traffic channel 2 for low speed data transmission in a next generation cellular mobile communication system.

Means for solving the problem

In order to solve the above problems, a channel assignment method with a higher degree of freedom, which is different from now, is required. That is, the traffic channel and the control channel are multiplexed using a signal that is not orthogonal to any of the time axis, frequency axis, and code.

By using non-orthogonal signals, the control channel and traffic channel interfere with each other. In general, traffic channels are fast and require a lot of power for their transmission. On the other hand, the control channel is low speed and the power of the entire channel is small. However, if an error occurs in the control channel, there is a possibility that the data of the traffic channel cannot be processed correctly, so that the control channel requires a high communication quality. Since the ratio of the power of the control channel to the entire signal is small, even if the power of the control channel is increased, the influence on the entire signal is small. Therefore, the power distribution of the control channel is set a little larger to reduce the error rate. As a result, the control channel can be accurately received even if it receives interference from the traffic channel.

Increasing the power of the control channel also increases the interference from the control channel to the traffic channel. This problem can be solved by using an interference cancellation (cancelling) technique as necessary. If the channel quality is high enough, it is possible to receive a traffic channel without using interference cancellation. When the communication channel quality is low, a method of generating a replica (replicator) of the control channel signal after determining the control channel symbol and a method of generating a replicator by decoding and recoding the control channel can be applied. Can be used according to the quality.

When the control channel contains the information of the traffic channel transmitted in the same frame, it is necessary to process the control channel first to determine whether or not the information to the traffic channel is included in the traffic channel, and to perform reception processing on unnecessary traffic channels. There is no. If the traffic channel contains information to the local station and the communication path quality is not very good, it is possible to suppress the deterioration of the traffic channel by generating a signal replicator of the control channel and canceling it from the received signal. This is also valid when the control channel included in the previously sent frame contains the information of the traffic channel of the frame to be sent later.

In addition, although it has been explained by a combination of a high speed traffic channel and a low speed control channel, most functions can be applied as it is even when there are two traffic channels having different speeds. It is not limited to a combination.

EMBODIMENT OF THE INVENTION Below, the means to solve the subject of this invention is demonstrated more concretely.

A first technical means is a communication system using an orthogonal frequency division multiplexing (OFDM) technique, comprising a traffic channel for transmitting traffic data and a control channel for transmitting control data, wherein the traffic channel signal is generated using OFDM modulation. And a transmission signal is generated by multiplexing a control channel signal generated using a signal that is not orthogonal to any of time, frequency, and code with respect to the traffic channel signal.

The second technical means is the first technical means, wherein the control channel signal is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions of the OFDM modulated traffic channel signal. .

The third technical means is the first technical means, wherein the control channel signal is a signal encoded by a low rate block code, and the code word is a signal configured to be transmitted using a plurality of subcarriers of a single OFDM symbol. It is a feature.

The fourth technical means is a first technical means, on the receiving station side, the traffic channel and the control channel are multiplexed to the received signal from the received symbol obtained by receiving a signal multiplexed with the traffic channel and demodulating the control channel to determine a signal point. After generating a duplicate of the control channel signal and removing the control channel signal component from the received signal, demodulation of the traffic channel is performed.

The fifth technical means is the first technical means, wherein the control channel data is error corrected and coded, and on the receiving station side, the control channel obtained by receiving a signal multiplexed with the traffic channel and the control channel, and demodulating and decoding the control channel. It is characterized in that a demodulation process of the traffic channel is performed after generating a duplicate of the control channel signal multiplexed with the received signal from the data, removing the control channel signal component from the received signal.

The sixth technical means is the first technical means, wherein the data of the control channel is error-corrected coded, and the data of the control channel includes destination information of the traffic channel transmitted at or after that time. Receiving a signal multiplexed with the traffic channel and the control channel, demodulating and decoding the control channel to extract the control channel data, and whether the traffic channel includes information from the control channel obtained in the past or at that time. If it is determined that the traffic channel includes information forwarded to the local station, a duplicate of the control channel signal multiplexed to the received signal is extracted from the extracted control channel data, and after removing the control channel signal component from the received signal, The demodulation process is performed.

A seventh technical means is a communication system using an orthogonal frequency division multiplexing (OFDM) technique, comprising: traffic channel 1 for transmitting high speed traffic data and traffic channel 2 for transmitting low speed traffic data, and using OFDM modulation. Generating a transmission signal by multiplexing a signal of traffic channel 1 generated by using a signal of traffic channel 2 generated using a signal that is not orthogonal to any of time, frequency, and code with respect to the signal of traffic channel 1 generated by It is a feature.

The eighth technical means is the seventh technical means, wherein the signal of the traffic channel 2 is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions of the signal of the OFDM modulated traffic channel 1, or both thereof. It is a feature.

The ninth technical means is the seventh technical means, wherein the signal of traffic channel 2 is a signal encoded by a low rate block code, and the code word is a signal configured to be transmitted using a plurality of subcarriers of a single OFDM symbol. It is characterized by that.

The tenth technical means is a seventh technical means, on the receiving station side, a symbol of traffic channel 2 obtained by receiving a signal multiplexed with traffic channel 1 and traffic channel 2, demodulating traffic channel 2, and determining a signal point. Demodulating the traffic channel 1 after generating a duplicate of the signal of traffic channel 2 multiplexed with the received signal, removing the signal component of traffic channel 2 from the received signal.

The eleventh technical means is a seventh technical means in which data of traffic channel 2 is error corrected and coded, and on the receiving station side, a signal multiplexed by traffic channel 1 and traffic channel 2 is received, and demodulation and decoding of traffic channel 2 is performed. The traffic channel 2 is demodulated from the traffic channel 2 data obtained by generating a duplicate of the traffic channel 2 signal multiplexed to the received signal, and after removing the signal component of the traffic channel 2 from the received signal. .

A twelfth technical means is a transmission apparatus using orthogonal frequency division multiplexing (OFDM) modulation, comprising: means for OFDM-modulating traffic channel data to generate a traffic channel signal, and a time, frequency, or code for the traffic channel signal. Means for generating a control channel signal from the control channel data using a signal that is not orthogonal, and means for generating a transmission signal by multiplexing the traffic channel signal and the control channel signal.

The thirteenth technical means is the twelfth technical means, wherein the control channel signal generating means includes a control channel symbol for transmitting control channel data, a plurality of subcarriers or a plurality of OFDM symbols of an OFDM modulated traffic channel signal, or And means for diffusing over both regions.

The fourteenth technical means is the twelfth technical means, wherein the control channel signal generating means comprises: encoding means by a low rate block code and means for arranging the codeword to be transmitted using a plurality of subcarriers of a single OFDM symbol. It characterized in that it comprises a.

A fifteenth technical means is a receiving apparatus for receiving a signal transmitted from a twelfth technical means, which generates a duplicate of a control channel signal multiplexed with a received signal from a received signal obtained by demodulating a control channel to determine a signal point. Means and means for removing the control channel signal component from the received signal.

The sixteenth technical means is a receiving apparatus for receiving a signal transmitted from the twelfth technical means, wherein the control channel data is error corrected and coded, and the control multiplexed to the received signal from the control channel data obtained by demodulating and decoding the control channel. Means for generating a replica of the channel signal and means for removing the control channel signal component from the received signal.

A seventeenth technical means is a receiving apparatus for receiving a signal transmitted from a twelfth technical means, wherein data of a control channel is error corrected and coded, and has means for demodulating and decoding a control channel to extract control channel data. Alternatively, it is determined whether or not the traffic channel includes information forwarded to the local station from the control information obtained at that time, and when the traffic channel includes information forwarded to the local station, the control channel multiplexed to the received signal from the extracted control channel data. The traffic channel demodulation process is performed after generating a duplicate of the signal and removing the control channel signal component from the received signal.

An eighteenth technical means is a receiving apparatus for receiving a signal transmitted from a twelfth technical means, and is a replica of a control channel from a control channel symbol obtained by receiving a signal multiplexed with a traffic channel and a control channel, and demodulating and determining a control channel. Canceling function 1 for removing the control channel signal component from the received signal, and receiving a signal multiplexed with the traffic channel and the control channel and demodulating and decoding the control channel. Has a canceling function 2 that creates a duplicate of the channel and removes the control channel signal component from the received signal and, depending on the quality of the communication path, selects one of the canceling function 1, the canceling function 2, and no canceling The demodulation process is performed.

A nineteenth technical means is a receiving apparatus for receiving a signal transmitted from a twelfth technical means, and is multiplexed to a received signal from control channel symbols obtained by receiving a signal multiplexed with a traffic channel and a control channel, and demodulating and determining a control channel. A canceling function 1 for generating a duplicate of the control channel signal, removing the control channel signal component from the received signal, and a control channel data obtained by receiving a signal multiplexed with the traffic channel and the control channel and demodulating and decoding the control channel. Has only one canceling function of either of the two canceling functions of the canceling function 2, which creates a duplicate of the control channel multiplexed into the received signal and removes the control channel signal component from the received signal, due to the quality of the communication channel, canceling Demodulating the traffic channel by selecting any one of?,?, And no cancellation? Will.

A twentieth technique means is a transmission apparatus using orthogonal frequency division multiplexing (OFDM) modulation, comprising: means for OFDM-modulating data on traffic channel 1 to generate a signal of traffic channel 1, and a time, Means for generating a signal of traffic channel 2 using a signal that is not orthogonal to any of frequency and code, and means for generating a transmission signal by multiplexing the signal of traffic channel 1 and the signal of traffic channel 2; It is.

The twenty-first description means is the twentieth description means, and the signal generation means of the traffic channel 2 includes a plurality of subcarriers or a plurality of OFDM symbols of a signal of the OFDM-modulated traffic channel 1 for transmitting the traffic channel 2; Or means for diffusing over both areas.

The twenty-second description means is a twentieth description means, and the signal generation means of traffic channel 2 is arranged such that the encoding means by a low rate block code and the codeword are transmitted using a plurality of subcarriers of a single OFDM symbol. It characterized in that it comprises a means for.

A twenty-third technical means is a receiving apparatus for receiving a signal transmitted from a twentieth technical means, and is characterized in that traffic channel 2 multiplexed to a received signal from a symbol of traffic channel 2 obtained by demodulating traffic channel 2 to determine a signal point. Means for generating a replica of the signal and means for removing the signal component of traffic channel 2 from the received signal.

The twenty-fourth technical means is a reception apparatus for receiving a signal transmitted by the twentieth technical means, and the data of the traffic channel 2 is error corrected and received from the data of the traffic channel 2 obtained by demodulating and decoding the traffic channel 2. Means for replicating the signal of traffic channel 2 multiplexed to the signal and means for removing the signal component of traffic channel 2 from the received signal.

A twenty-fifth technical means is a reception apparatus for receiving a signal transmitted by a twentieth technical means, and generates a duplicate of a signal of a traffic channel 2 multiplexed with a received signal from a symbol of the traffic channel 2 obtained by demodulating and determining the traffic channel 2. A cancellation function 1 for removing the signal component of traffic channel 2 from the received signal and a copy of the signal of traffic channel 2 multiplexed with the received signal from the data of traffic channel 2 obtained by demodulating and decoding the traffic channel 2, Having a canceling function 2 for removing the signal component of the traffic channel 2 from the received signal, and demodulating the traffic channel 1 by selecting one of the canceling function 1, the canceling function 2, and no canceling depending on the quality of the communication path. It is a feature.

A twenty-sixth technical means is a reception apparatus for receiving a signal transmitted by the twentieth technical means, and generates a duplicate of the signal of the traffic channel 2 multiplexed to the received signal from the symbol of the traffic channel 2 obtained by demodulating and determining the traffic channel 2. A cancellation function 1 for removing the signal component of traffic channel 2 from the received signal, and a copy of traffic channel 2 multiplexed with the received signal from the data of traffic channel 2 obtained by demodulating and decoding the traffic channel 2; The canceling function of the two canceling functions of the canceling function 2 which removes the signal component of the traffic channel 2 from the traffic channel 1 by selecting one of the canceling function and the canceling function according to the quality of the communication channel. It is characterized by demodulating.

The twenty-seventh technical means uses orthogonal frequency division multiplexing (OFDM), and the OFDM modulated signal is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions thereof. A transmission apparatus using a modulation scheme (OFCDM modulation), which is orthogonal to any of time, frequency, and code with respect to a traffic channel signal generating means for OFCDM-modulating traffic channel data to generate a traffic channel signal. And a control channel signal generating means for generating a control channel signal from the control channel data using an unsigned signal, and a transmission signal generating means for generating a transmission signal by multiplexing the traffic channel signal and the control channel signal. .

The twenty-eighth technical means uses Orthogonal Frequency Division Multiplexing (OFDM), and the OFDM modulated signal is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions thereof. A transmission apparatus using a modulation scheme (OFCDM modulation), comprising: traffic channel signal generating means for generating traffic channel signals by OFCDM modulation of traffic channel data, and generating control channel signals by modulating control channel data in an arbitrary manner. Switching means for switching the control channel signal generating means, the control channel signal and the traffic channel signal into signals that are not orthogonal to any of time, frequency, or code, and signals that are orthogonal to any of the time, frequency, or code; And transmission signal generating means for generating a transmission signal by multiplexing the traffic channel signal and the control channel signal. It is the one characterized.

The twenty-ninth technical means, in the twenty-eighth technical means, the switching means switches to a signal that is not orthogonal when the quality of the communication path is good, and switches to an orthogonal signal when the quality of the communication path is poor. I did it.

The thirtieth technical means is that, in the twenty-eighth technical means, the switching means switches a signal orthogonal to a non-orthogonal signal according to the number of spreading codes currently used in the traffic channel signal.

The thirty-first description means is any one of the twenty-seventh description means to the thirtieth description means, wherein the control channel signal generated by the control channel signal generating means is an OFCDM modulated signal.

The thirty-second description means is a twenty-seventh description means, wherein the control channel signal generating means comprises: encoding means by a low rate block code and means for arranging the code word to be transmitted using a plurality of subcarriers of a single OFDM symbol. It characterized in that it comprises a.

The thirty-third technical means is any one of the twenty-seventh technical means to the thirty-third technical means, wherein the control channel signal processing means for demodulating the control channel data from the control channel signal, and OFCDM demodulates the traffic channel signal to traffic Traffic channel signal processing means for demodulating the channel data, means for demodulating the control channel signal, generating a duplicate of the control channel signal multiplexed into the received signal from the demodulated signal, and removing the control channel signal component from the received signal. And control channel canceller means comprising means for.

The thirty-fourth description means, in the thirty-third description means, wherein the control channel canceler means duplicates the control channel signal multiplexed with the received signal from the control channel symbol obtained by the determination means for demodulating the control channel signal to determine the signal point. And demodulate the traffic channel signal after removing the control channel signal component from the received signal.

The thirty-fifth technique means, in the thirty-third technique means, the control channel canceler means generates a duplicate of the control channel signal multiplexed with the received signal from the control channel data obtained by demodulating the control channel signal and decoding it in the error correction code decoding means. After the control channel signal component is removed from the received signal, the demodulation process of the traffic channel signal is performed.

The thirty-sixth technical means, in the thirty-fourth technical means or the thirty-fifth technical means, the control channel canceler means determines whether or not the information to the traffic channel is included in the traffic channel from the control information obtained in the past or at that time, In the case where the channel includes information forwarded to the own station, a duplicate of the control channel signal multiplexed to the received signal is generated, and after removing the control channel signal component from the received signal, the demodulation process of the traffic channel signal is performed. .

The thirty-seventh technical means, in the thirty-third technical means, the control channel canceler means demodulates the control channel signal, and generates, by the determining means, a duplicate of the control channel from the control channel symbol obtained by determining the signal point. Canceling (1) means for removing the control channel signal component from the received signal, and a copy of the control channel multiplexed with the received signal from the control channel data obtained by demodulating and decoding the control channel, and generating the control channel signal component from the received signal. And a means for canceling the traffic channel by selecting one of the means for canceling (1), the means for canceling (2), and a means for not canceling according to the quality of the communication path. It is characterized by doing.

The thirty-eighth technical means, in the thirty-third technical means, wherein the control channel canceler means is configured to receive a signal multiplexed with a traffic channel and a control channel, and to control multiplexed to a received signal from a control channel symbol obtained by demodulating and determining a control channel. Canceling (1) means for generating a duplicate of the channel signal, removing the control channel signal component from the received signal, and receiving a signal multiplexed with the traffic channel and the control channel, and receiving from the control channel data obtained by demodulating and decoding the control channel. One of the two canceling means of the canceling (2) means for generating a duplicate of the control channel multiplexed into the signal and removing the control channel signal component from the received signal; The demodulation of the traffic channel is performed by selecting whether to execute or not.

A thirty-third technical means is a receiving apparatus that receives a signal transmitted from a transmitting apparatus in any one of the twenty-eighth technical means to thirtieth technical means, and OFCDM demodulates a traffic channel signal to perform demodulation processing of traffic channel data. A traffic channel signal processing means for performing the control, a control channel signal processing means for demodulating the control channel data from the control channel signal, and a signal in which the control channel signal and the traffic channel signal are not orthogonal to each other in time, frequency, or code; And switching means for switching time, frequency or code so as to demodulate any of the signals orthogonal to any one of time, frequency and code, and multiplexing to a received signal from received symbols or received data obtained by demodulating the control channel. Copying means for generating a copy of the received control channel signal and controlling from the received signal Control channel canceller means including removal means for removing null signal components, and if the control channel is the orthogonal signal, demodulation of the traffic channel as it is; and if the control channel is the non-orthogonal signal, control channel cancellation And demodulating the traffic channel after canceling the control channel from the received signal by the means.

A forty-first description means is a reception device that receives a signal transmitted from a transmission device in any one of the twenty-eighth technology to the thirtieth technology means, and OFCDM demodulates the traffic channel signal to perform demodulation processing of the traffic channel data. A traffic channel signal processing means for performing the control, a control channel signal processing means for demodulating the control channel data from the control channel signal, and a signal in which the control channel signal and the traffic channel signal are not orthogonal to each other in time, frequency, or code; And switching means for switching time, frequency or code so as to demodulate any of the signals orthogonal to any one of time, frequency and code, and multiplexing to a received signal from received symbols or received data obtained by demodulating the control channel. Copying means for generating a copy of the received control channel signal and controlling from the received signal A control channel canceler means including removal means for removing a null signal component, the control channel canceler means being replicated by means of replication means depending on the quality of the communication path and whether it is an orthogonal or non-orthogonal signal. Using the received signal, it is determined whether or not to cancel the control channel from the received signal by the removing means, selects it, and demodulates the traffic channel.

The forty-first description means uses orthogonal frequency division multiplexing (OFDM), and the OFDM modulated signal is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions thereof. A transmission apparatus using a modulation scheme (OFCDM modulation), which comprises: traffic channel signal 1 generating means for OFCDM-modulating traffic channel data 1 to generate traffic channel signal 1, and a time, frequency, code for the signal of traffic channel 1; Traffic channel signal 2 generating means for generating traffic channel signal 2 from traffic channel data 2, which is low-speed traffic channel data, using a signal that is not orthogonal to any of the traffic channel data 1, and traffic channel signal 1; And transmission signal generating means for generating a transmission signal by multiplexing the traffic channel signal 2 with each other. to be.

The 42nd technique means uses Orthogonal Frequency Division Multiplexing (OFDM) technique, and the signal which was OFDM-modulated by OFDM technique is the signal spread over the several subcarrier, the several OFDM symbol, or both areas. A transmission apparatus using a modulation scheme (OFCDM modulation), comprising: traffic channel signal 1 generating means for OFCDM-modulating traffic channel data 1 to generate traffic channel signal 1, and traffic channel data 2 by arbitrarily modulating traffic channel data 2 Traffic channel 2 signal generating means for generating a signal of 2, a signal of traffic channel 2 and a signal of traffic channel 1 are not mutually orthogonal to any of time, frequency, or code, A switching means for switching to a signal orthogonal to either one, and a transmission signal is generated by multiplexing the traffic channel signal 1 and the traffic channel signal 2; Is one characterized in that it includes a transmission signal generating means.

In the forty-third technical means, in the forty-second technical means, the switching means switches to non-orthogonal signals when the quality of the communication path is good, and switches to orthogonal signals when the quality of the communication path is poor. will be.

The forty-fourth description means, in the forty-eighth description means, the switching means for switching the signal orthogonal to the non-orthogonal signal according to the number of spreading codes currently used in the signal of the traffic channel 1.

The forty-fifth technical means is any one of the forty-first technical means for the forty-fourth technical means, wherein the traffic channel 2 signal generated by the traffic channel signal 2 generating means is an OFCDM modulated signal. .

The forty-sixth technical means is the forty-first technical means, wherein the traffic channel signal two generating means is arranged so that the encoding means by a low rate block code and the codeword are transmitted using a plurality of subcarriers of a single OFDM symbol. It comprises a means.

A forty-seventh technical means is a receiving apparatus for receiving a signal transmitted by a transmitting apparatus in any one of the forty-first technical means to forty-eighth technical means, and OFCDM demodulation of traffic channel signal 1 to demodulate traffic channel data 1. Traffic channel 1 signal processing means for performing processing, traffic channel 2 signal processing means for performing demodulation processing of traffic channel data 2 which is low-speed traffic channel data from traffic channel signal 2 to traffic channel data 1, and a received signal Traffic channel 2 canceller means comprising means for generating a replica of the traffic channel signal 2 multiplexed on the signal and means for removing a component of the traffic channel signal 2 from the received signal.

The forty-eighth technical means, as the forty-seventh technical means, is a traffic channel multiplexed to a received signal by traffic channel canceller means from traffic channel data 2 obtained by demodulating traffic channel 2 and decoding by error correction code decoding means. Generate a duplicate of signal 2 and remove the signal component of traffic channel 2 from the received signal.

The forty-ninth technical means is a forty-ninth technical means, which demodulates the traffic channel signal 2 and multiplexes the received signal by the traffic channel canceler means from the symbol of the traffic channel 2 obtained by the determination means for determining the signal point. It will be characterized by generating a duplicate of the traffic channel signal 2, and removing the component of traffic channel signal 2 from the received signal.

The fifty-seventh technical means is a forty-seventh technical means, wherein the traffic channel canceller means is demodulated by the traffic channel 2 and multiplexed to the received signal from the symbol of the traffic channel 2 obtained by determining the signal point by the determining means. Traffic channel data 2 obtained by generating a duplicate of traffic channel signal 2, canceling 1 means for removing the component of traffic channel signal 2 from the received signal, and demodulating traffic channel 2 and decoding by error correction code decoding means. Means for generating a duplicate of traffic channel signal 2 multiplexed from the received signal to the received signal, and for canceling the signal component of traffic channel 2 from the received signal, by means of the quality of the communication path; Demodulation of traffic channel 1 by selecting one of the canceling (2) means and a means of not canceling; .

The fifty-first description means is a forty-seventh description means, wherein the traffic channel canceler means generates a duplicate of the signal of the traffic channel 2 multiplexed with the received signal from the symbol of the traffic channel 2 obtained by demodulating and determining the traffic channel 2, Canceling (1) means for removing components of the traffic channel signal 2 from the received signal, and a copy of the traffic channel 2 multiplexed with the received signal from the traffic channel data 2 obtained by demodulating and decoding the traffic channel 2, and It is provided with only one of the two canceling means of the canceling means 2 of the canceling means 2 for removing the component of the traffic channel signal 2, and according to the quality of the communication path, it is selected whether or not to perform the canceling. Demodulation is performed.

The twenty-second description means is a reception device that receives a signal transmitted from a transmission device in any one of the forty-second technical means to the forty-fourth technical means, and OFCDM demodulates the traffic channel signal 1 to demodulate the traffic channel data 1. The traffic channel 1 signal processing means for processing, the traffic channel 2 signal processing means for demodulating the traffic channel signal 2 and demodulating the traffic channel data 2, and the traffic channel signal 1 and the traffic channel signal 2 are mutually time and frequency. Demodulation means for switching time, frequency or code so that a signal that is not orthogonal to any of the codes, a signal orthogonal to any one of time, frequency or code can be demodulated, and traffic channel signal 2 To generate a duplicate of the traffic channel signal 2 multiplexed on the received signal from the received symbol or received data. Traffic channel 2 canceller means including copying means and removing means for removing the component of traffic channel signal 2 from the received signal, and if traffic channel signal 2 is a orthogonal signal, demodulation of traffic channel data 1 is performed as it is. If the traffic channel signal 2 is not orthogonal, the traffic channel signal 1 is demodulated after the traffic channel signal 2 is canceled from the received signal by the signal copied by the traffic channel 2 canceller means.

A fifty-third description means is a reception device that receives a signal transmitted from a transmission device in any one of the forty-second description means to the forty-eighth description means, and OFCDM demodulates the traffic channel signal 1 to demodulate the traffic channel data 1. The traffic channel 1 signal processing means for processing, the traffic channel 2 signal processing means for demodulating the traffic channel signal 2 and demodulating the traffic channel data 2, and the traffic channel signal 1 and the traffic channel signal 2 are mutually time and frequency. Demodulation means for switching time, frequency or code so that a signal that is not orthogonal to any of the codes, a signal orthogonal to any one of time, frequency or code can be demodulated, and traffic channel signal 2 To generate a duplicate of the traffic channel signal 2 multiplexed on the received signal from the received symbol or received data. Traffic channel 2 canceller means including replication means and removal means for removing a component of traffic channel signal 2 from the received signal, wherein the traffic channel 2 canceller means is a signal of orthogonality and orthogonal signal; According to whether or not the signal is not used, it is determined whether or not to cancel the traffic channel signal 2 from the received signal by the removing means using the signal copied by the copying means, and selects the demodulated data of the traffic channel data 1. It is characterized by performing.

The fifty-fourth technical means includes a transmitting device in any one of the twenty-seventh technical means to a thirty-second technical means, and a receiving apparatus in any one of the thirty-third technical means to thirty-eight technical means. It is a data communication system characterized by the above-mentioned.

The fifty-fifth technical means includes a transmitting device in any one of the twenty-eighth technical means or the thirty-first technical means, and a receiving apparatus in the thirty-third technical means or the forty-fifth technical means. to be.

The fifty-sixth technical means includes a receiving apparatus in any one of the forty-first technical means to the forty-sixth technical means, and a receiving apparatus in any one of the forty-ninth technical means to fifty-first technical means. It is a data communication system characterized by the above-mentioned.

57th technical means is equipped with the transmission apparatus in any one of the 42nd technical means, and the 45th technical means, and the receiving apparatus in any one of the 52nd technical means, or 53rd technical means. It is a data communication system characterized by the above-mentioned.

Effect of the Invention

If a part of a plurality of subcarriers is allocated as a control channel like SCS-MC-CDMA, a specific subcarrier cannot be used for data transmission. In addition, if a code orthogonal to the traffic channel and the control channel is assigned like the VSF-OFCDM, it is impossible to assign a spreading code to the traffic channel. For example, when the spreading rate of the traffic channel is 8, even if the control channel is low and the spreading rate corresponding to the required transmission rate is 128, only 7 codes can be assigned to the traffic channel, and the transmission rate is lowered.

In contrast, in the present invention, it is possible to multiplex the control channel without reducing the transmission speed of the traffic channel. In addition, the use of a canceller to remove control channel components can minimize the quality degradation of the traffic channel.

In addition, according to the transmitting apparatus, receiving apparatus and communication system according to the present invention, when OFCDM is used as a control channel, a code orthogonal to a spreading code used in a traffic channel depends on the quality of the communication path and the number of codes in use. By using or by using non-orthogonal codes, it becomes possible to transmit more efficiently.

1 is a block diagram of a transmitter according to Embodiment 1 of the present invention;

2 is a block diagram of a traffic channel signal generator and a control channel signal generator according to Embodiment 1 of the present invention;

3 is a block diagram of a control channel signal generation unit according to Embodiment 2 of the present invention;

4 is a block diagram of a control channel signal generator according to Embodiment 3 of the present invention;

5 is a block diagram of a transmitter according to Embodiment 4 of the present invention.

6 is a block diagram of a traffic channel signal control channel signal generation unit according to Embodiment 4 of the present invention;

7 is a block diagram of a transmitter according to Embodiment 5 of the present invention.

8 is a block diagram of a traffic channel control channel signal generation unit according to Embodiment 5 of the present invention;

9 is a block diagram of a receiver according to Embodiment 6 of the present invention;

10 is a block diagram of a control channel signal canceller unit in accordance with embodiments 6 and 7 of the present invention;

11 is a block diagram of a receiver according to Embodiment 7 of the present invention.

12 is a block diagram of a control channel signal canceller unit in accordance with embodiments 7 and 9 of the present invention;

Fig. 13 is a block diagram of a receiver according to Embodiment 8 of the present invention.

14 is a block diagram of a receiver according to Embodiment 9 of the present invention;

Fig. 15 is a block diagram of a receiver according to Embodiment 10 of the present invention.

16 is a block diagram of a control channel signal canceller unit according to Embodiment 10 of the present invention;

17 is a flowchart of a receiver according to Embodiment 11 of the present invention.

18 is a flowchart of a receiver according to Embodiment 12 of the present invention.

19 is a block diagram of a transmitter according to Embodiment 13 of the present invention.

20 is a block diagram of a traffic channel signal generator and a control channel signal generator of a transmitter according to Embodiment 13 of the present invention.

21 is a block diagram of a control channel signal generator of a transmitter according to Embodiment 14 of the present invention;

22 is a block diagram of a control channel signal generator of a transmitter according to Embodiment 15 of the present invention;

23 is a block diagram of a transmitter according to Embodiment 16 of the present invention.

24 is a block diagram of a traffic channel signal control channel signal generator of a transmitter according to Embodiment 16 of the present invention;

25 is a block diagram of a transmitter according to Embodiment 17 of the present invention.

26 is a block diagram of a traffic channel control channel signal generation unit according to Embodiment 17 of the present invention.

27 is a block diagram of a receiver according to Embodiment 18 of the present invention.

Fig. 28 is a block diagram of a control channel signal canceller unit of the receiver according to Embodiment 18 of the present invention.

29 is a block diagram of a receiver according to Embodiment 19 of the present invention.

30 is a block diagram of a control channel signal canceller part of the receiver according to Embodiment 19 of the present invention;

Figure 31 is a block diagram of a receiver according to Embodiment 20 of the present invention.

32 is a block diagram of a receiver according to Embodiment 21 of the present invention.

33 is a block diagram of a receiver according to Embodiment 22 of the present invention.

34 is a block diagram of a control channel signal canceller unit of the receiver according to Embodiment 22 of the present invention.

35 is a block diagram of a traffic channel signal generator, a control channel signal generator, and an orthogonal code generator of a transmitter according to Embodiment 23 of the present invention;

36 is a block diagram of a receiver according to Embodiment 24 of the present invention.

37 is a block diagram of a receiver according to Embodiment 25 of the present invention.

38 is a flowchart showing an operational flow of a receiver according to Embodiments 20 and 21 of the present invention.

39 is a flowchart showing an operational flow of a receiver according to Embodiments 20 and 21 of the present invention.

FIG. 40 is a flow chart showing an operation flow of a receiver according to Embodiment 25 of the present invention. FIG.

Fig. 41 is a block diagram of general OFDM.

FIG. 42 is a diagram illustrating a guard interval of an OFDM signal. FIG.

43 is a diagram showing a configuration of an OFDM signal.

Fig. 44 is a diagram showing a configuration of an OFCDM signal.

45 is a block diagram of a typical OFCDM.

<Description of the code>

1, 5, 24, 100, 104, 1023, 1121, 1444: FEC encoder

2, 6, 25, 101, 105, 1025, 1122, 1445: interleaver

3, 7, 26, 102, 106, 702, 1026, 1123, 1226, 1446: MOD

4, 103: traffic channel signal generation unit

8, 107, 300, 400: control channel signal generator

9: Traffic channel control channel signal generator

11: Timing detection / channel estimation process

12, 234, 950, 1011, 1110, 1210, 1310, 1410: Remove GI

13, 904, 956, 1012, 1124, 1217, 1420: memory

14, 905, 957, 1013, 1125, 1218, 1447: control channel signal canceller

15: Despreading Treatment

16, 21, 156, 908, 911, 953, 961, 1020, 1033, 1118, 1129, 1222, 1361, 1364, 1441, 1449: Demod

17, 22, 909, 912, 954, 962, 1021, 1034, 1119, 1130, 1223, 1362, 1365, 1442, 1450: deinterleaver

18, 23, 157, 910, 913, 963, 975, 1022, 1035, 1120, 1131, 1224, 1363, 1366, 1443, 1451: decoder

19, 907, 955: judgment unit

20, 958, 1126, 1219: Traffic channel processing

41, 81, 87, 91, 92, 141, 151, 201, 230, 230a, 230b, 236, 920a, 920b, 930, 970, 980, 1015, 1028, 1113, 1213, 1320: S / P conversion

44, 85, 97, 155, 204, 205, 232, 232a, 232b, 238, 924a, 924b, 933, 960, 974, 1019, 1032, 1117, 1128, 1216, 1221: P / S conversion

42, 83, 95, 143, 202a, 202b: scrambled

82, 88, 90, 93, 99, 142, 201a, 201b, 301, 401: Frequency Domain Diffusion Processing

43, 84, 96, 231, 231a, 231b, 932: IFFT processing

45, 86, 98, 233, 233a, 233b: Add GI

89, 302: MUX

144: multiply channel estimate

94, 147, 148: +

152, 202, 237, 921a, 921b, 971, 1016, 1029, 1114, 1214, 1330: FFT processing

153, 203, 922a, 922b, 972, 1017, 1030, 1115, 1215: descramble

108, 1350, 1440: Orthogonal Code Generator

109: Orthogonal Code Generator 1

110: Orthogonal Code Generator 2

111: code changer

235: timing detector

240: GI

500, 700: traffic channel and control channel signal generator

501, 934: adder

701, 1225: Enc

271, 900, 951, 1010, 1211, 1300, 1400: timing detection and channel estimation processing

903 and 1112: control channel signal processing unit

1212 and 1430: control channel data signal processor

1340: control channel data signal processor 2

906, 952, 1014, 1027, and 1448: traffic channel signal processing unit

1360: traffic data signal processing unit 2

154, 272, 923a, 923b, 959, 973, 1018, 1031, 1116, 1127, 1220: Frequency Domain Despreading

270a, 270b, 931a, 931b: copying machine

(Example 1)

In most wireless communication systems, in addition to traffic data exchanged between the user terminal and the other terminal, such as audio data, video data, and other packet data, control information exchanged with the system for operation on the wireless communication system, Control information indicative of the nature of the transmitted traffic data is communicated.

As shown in Fig. 1, in the present invention, the traffic channel data and the control channel data are separately encoded in the FEC encoders 1 and 5, interleaved in the interleavers 2 and 6, and modulated in the MODs 3 and 7. The traffic channel data symbol is converted into a traffic channel signal in the traffic channel signal generator 4, and the control channel symbol is converted into a control channel signal in the control channel signal generator 8. These signals are added as they are and transmitted.

Details of the traffic channel signal generator 4 and the control channel signal generator 8 are shown in FIG. In the traffic channel signal generation unit 4 of FIG. 2A, after the S / P conversion (serial-parallel conversion) 41, the cell-specific scrambling code is multiplied (scramble 42), and the inverse fast Fourier transform is performed. Processing (IFFT processing) 43 is performed. Then, the P / S conversion (parallel series conversion) 44 is used as a time signal sequence, and the Add GI 45 gives a guard interval.

In the control channel signal generation section 8 of FIG. 2B, after the S / P conversion 81, the control channel symbols are copied so as to be transmitted by a plurality of subcarriers and multiplied by spreading codes to thereby spread the frequency domain (82). Thereafter, similar to the traffic channel signal generation unit 4, the cell-specific scrambling code is multiplied (scramble 83), and an inverse fast Fourier transform process (IFFT process) 84 is performed. In addition, P / S conversion 85 is used as a time signal sequence, and a guard interval is given by Add GI 86.

(Example 2)

An embodiment of transmission signal generation using a method of generating a control channel different from Embodiment 1 will be described. Although the block diagram of FIG. 1 and the traffic channel signal generator 4 of FIG. 2 are common to the first embodiment, the structure of the control channel signal generator 8 differs from the first embodiment in this embodiment. This part is shown in FIG. In the control channel signal generation section 8 of FIG. 3, the control channel symbols are distributed one symbol to the spread code by the S / P conversion 87. FIG. Each spreading code is a code in which code length N (= number of subcarriers) is orthogonal. The spreading code is used to spread the frequency domain with a spreading rate N (frequency domain spreading process 88), and then MUX 89 Code multiplexing). Inverse Fourier transform processing (IFFT processing) 84 is performed by multiplying the cell-specific scrambling code, and the P / S transform 85 is used as a time signal string, and a guard interval is given by Add GI 86. .

In Example 2, compared with Example 1, a diffusion rate can be enlarged. As the spreading rate increases, the code multiplexing is performed so that the transmission rate of the control channel does not change. The method of Embodiment 2 can be used to average the interference from the traffic channel by increasing the spread rate. In addition, by spreading widely in the frequency domain, the frequency diversity effect can be increased.

(Example 3)

Another embodiment of transmission signal generation using a method of generating a control channel different from Embodiment 1 will be described. In the present embodiment, the block diagram of FIG. 1 and the traffic channel signal generator 4 of FIG. 2 are common to the first embodiment. 4 shows the configuration of the control channel signal generator 8 of the present embodiment. The control channel signal generator 8 distributes the control channel symbol to the spread code by the S / P conversion 87. After that, further S / P conversion is performed to perform frequency domain spreading (frequency domain spreading process 90), and code multiplexing is performed in MUX 89. FIG. Thereafter, a cell-specific scrambling code is multiplied (scramble 83), and an inverse fast Fourier transform process (IFFT process) 84 is performed. In addition, after setting the time signal sequence by the P / S conversion 85, the Add GI 86 gives a guard interval.

The method of Example 3 is considered to be the intermediate method of Examples 1 and 2. As the number of subcarriers increases, the configuration becomes complicated in the second embodiment where the spreading rate and the number of subcarriers are the same. Therefore, the method of Example 3 which suppresses the complexity while obtaining the averaging effect and the diversity effect of interference by increasing the spreading degree to some extent becomes effective.

(Example 4)

In FIG. 1, for the sake of simplicity, the process of generating the traffic channel signal and the control channel signal in the time domain is completely separate. However, when the same scrambling code is used in the traffic channel and the control channel, the process of multiplying the scrambling code is performed. From then on it is possible to commonize. FIG. 5 is a block diagram of a transmitter according to a fourth embodiment of the present invention, and FIG. 6 is a block diagram for explaining in detail the traffic channel control channel signal generation unit shown in FIG.

As shown in Fig. 5, the traffic channel data and the control channel data are separately encoded by the FEC encoders 1 and 5, interleaved by the interleavers 2 and 6, and modulated by the MODs 3 and 7, respectively. The symbol and the control channel symbol are input to the traffic channel control channel signal generation unit 9.

As shown in FIG. 6, in the traffic channel control channel signal generation unit 9, after performing the S / P conversion 91 and the S / P conversion 92, the frequency channel spreading process 93 Control channel symbols are respectively added (+ (94)), multiply the cell-specific scrambling code (scramble 95), and inverse Fourier transform processing (IFFT processing) 96 After a time signal string is formed by the P / S conversion 97, the Add GI 98 gives a guard interval.

(Example 5)

7 is a block diagram of a transmitter according to a fifth embodiment of the present invention, and FIG. 8 is a block diagram of a traffic channel control channel signal generation unit of the present embodiment.

As shown in Fig. 7, in the transmitter of the present embodiment, the control channel data is input to the traffic channel control channel signal generator 9 as it is. Since the processing of the traffic channel data is the same as that of the fourth embodiment (Fig. 5), repeated description is omitted.

In this embodiment, as shown in Fig. 8, in the traffic channel control channel signal generation unit 9, after performing S / P conversion 92 on the control channel data, the frequency domain spreading process 99 is performed. . Here, the S / P-converted control channel data is block coded by the block encoder Enc and modulated as each subcarrier component by the modulator MOD.

The block encoder Enc is a block encoder that outputs n bits of codewords to k bits of input information bits. Here, n is preferably a divisor of the number N of subcarriers. Assuming n is a divisor of N and a modulation method of each subcarrier is BPSK, control channel data are serial-to-parallel converted in units of k · N / n bits in the S / P conversion 92.

The encoding process is performed in a block encoder Enc placed in parallel, and N bits are output. N bits are BPSK modulated as each subcarrier component and multiplexed with the traffic channel signal (+ (94)).

In addition, in FIG. 8, since the process of a traffic channel signal is the same as that of Example 4 (FIG. 6), repeated description is abbreviate | omitted.

(Example 6)

9 is a block diagram showing the configuration of a receiver according to the sixth embodiment of the present invention. In the present embodiment, the received signal assumes that the signal transmitted from the transmitter as described in the first or fourth embodiment is received via a wireless communication path.

First, timing detection and channel estimation are performed by the timing detection / channel estimation process 11, and the timing and channel estimation value which cut out the received signal for performing an FFT process are calculated | required. From this channel estimate, the weighting coefficient multiplied by each subcarrier after FFT is determined. Here, the weighting coefficient is a complex airspace of the channel gain corresponding to the frequency component of each subcarrier in the communication path, but the method of determining the weighting coefficient is not limited to this method. The channel estimate is also used in the control channel signal canceller to generate a duplicate of the control channel signal.

In the received signal, the guard interval is removed in the Remove GI 12, and once accumulated in the memory 13, demodulation of the control channel is performed first. Since the control channel is subjected to OFCDM modulation that performs frequency domain spreading, the despreading process 15 is performed by using the complex conjugate of the spreading code used for spreading and the weighting coefficient obtained in the timing detection / channel estimation process 11. Here, S / P conversion 151, FFT processing 152, descramble 153, frequency domain despreading 154, and P / S conversion 155 are executed.

After the despreading process, control channel data is obtained via a demodulator (16), a deinterleaver (17), and a decoder (18).

In addition, after despreading, the determination unit 19 determines a symbol, creates a duplicate of the control channel signal in the control channel signal canceller unit, and stores the accumulated data in the memory 13 in the control channel signal canceller unit 14. The control channel signal component is removed from the received signal, and the OFDM demodulation process 20 is performed. Here, S / P conversion 201, FFT processing 202, descramble 203, and P / S conversion 204 are performed. The demodulator (Demod) 21, the deinterleaver 22, and the decoder 23 perform error correction decoding to obtain traffic channel data.

Details of the control channel signal canceller 14 are shown in FIG. With respect to the determined control channel symbol, similarly to the control channel signal generation unit 8 in FIG. 2, after the S / P conversion 141, the control channel symbol is copied so as to be transmitted by a plurality of subcarriers, and the spread code Multiply by to perform frequency domain spreading (frequency domain spreading process 142), and further multiply the cell-specific scrambling code (scramble 143). Here, after multiplying the channel estimate obtained by the channel estimator to each subcarrier component (channel estimate multiplication 144), an inverse fast Fourier transform process (IFFT process) 145 is performed. To obtain a duplicate of the time signal of the control channel signal. By subtracting this duplicated signal from the received signals stored in the memory (+ (147)), the received signal from which the control channel signal is canceled is obtained.

(Example 7)

In FIG. 9 and FIG. 10, cancellation is performed by a signal in the time domain. However, as shown in FIGS. 11 and 12, it is also possible to cancel each subcarrier in the frequency domain. 11 is a block diagram showing the configuration of a receiver according to the seventh embodiment of the present invention.

In the present embodiment, the despreading process 15 is performed on the received signal from which the guard interval has been removed in Remove GI 12. Here, the received signal is subjected to S / P conversion 151, the FFT process 152 is performed to convert each subcarrier component, and the signal at the time when the descramble 153 is performed is stored in the memory 13. The control channel signal is subjected to the frequency domain despreading process 154 and the P / S conversion 155 as it is, and then the symbol is determined (determination 19). The control channel signal canceller unit 14 cancels the control channel signal in the frequency domain, performs the P / S conversion 205 in the traffic channel processing 20, demodulates it in the demod 21, and deinterleaver 22. Deinterleaves at, and outputs traffic channel data via a decoder (23). In addition, repeated description is abbreviate | omitted about the function similar to FIG.

FIG. 12 is a diagram showing details of the control channel signal canceller unit 14 of FIG. Here, S / P conversion 141 is performed on the determined control channel symbol, and the frequency domain spreading 142 is performed by multiplying the spreading code. Then, after performing the channel estimate multiplication 144 that multiplies the channel estimate obtained by the timing detection / channel estimation process 11 to each subcarrier component, the signal at the time of descramble accumulated in the memory 13 (canceller). Subtract from (+ (148)) to obtain a received signal whose control channel signal has been canceled.

(Example 8)

13 is a block diagram showing the configuration of a receiver according to an eighth embodiment of the present invention. First, timing detection and channel estimation are performed by the timing detection / channel estimation process 11, and the timing and channel estimation value which cut out the received signal for performing an FFT process are calculated | required. From this channel estimate, the weighting coefficient multiplied by each subcarrier after FFT is determined.

The received signal is removed from the guard GI 12 by the guard interval, and once accumulated in the memory 13, first demodulating the control channel. Since the control channel is subjected to OFCDM modulation that performs frequency domain spreading, the despreading process 15 is performed by using the complex conjugate of the spreading code used for spreading and the weighting coefficient obtained in the timing detection / channel estimation process 11. Here, S / P conversion 151, FFT processing 152, descramble 153, frequency domain despreading 154, and P / S conversion 155 are executed.

After the despreading process, control channel data is obtained via a demodulator (16), a deinterleaver (17), and a decoder (18).

In the present embodiment, the control channel data decoded by the decoder 18 is again encoded by the FEC encoder 24, interleaved by the interleaver 25, and modulated by the MOD 26 to cancel the control channel signal. It is sent to the rubbing part 14.

The control channel signal canceller 14 is similar to the block of FIG. 10 already described, and after performing the S / P conversion 141, copies the control channel symbol to be transmitted by a plurality of subcarriers and multiplies the spread code. As a result, frequency domain spreading is performed (frequency domain spreading process 142), and a cell-specific scrambling code is multiplied (scramble 143). Here, after multiplying the channel estimate obtained by the channel estimator to each subcarrier component (channel estimate multiplication 144), an inverse Fourier transform process (IFFT process) 145 and a P / S transform 146 are performed. A replica of the time signal of the control channel signal is obtained. By subtracting this duplicated signal from the received signals stored in the memory (+ (147)), the received signal from which the control channel signal is canceled is obtained.

Then, the OFDM demodulation process 20 is performed. Here, S / P conversion 201, FFT processing 202, descramble 203, and P / S conversion 204 are performed. The demodulator 21, the deinterleaver 22, and the decoder 23 perform error correction decoding to obtain traffic channel data.

(Example 9)

14 is a block diagram showing the configuration of a receiver according to a ninth embodiment of the present invention. The despreading process 15 is performed on the received signal from which the guard interval has been removed from the Remove GI 12, but here, the received signal is subjected to S / P conversion 151, and the FFT process 152 is performed to perform each sub. The signal is converted into a carrier component and the signal at the time when the descramble 153 is performed is stored in the memory 13. The control channel signal is subjected to the frequency domain despreading process 154 and P / S conversion 155 as it is.

After the despreading process, control channel data is obtained via a demodulator 16, a deinterleaver 17, and a decoder 18.

In the present embodiment, the control channel data once decoded by the decoder 18 is again encoded by the FEC encoder 24, interleaved by the interleaver 25, and modulated by the MOD 26, and the control channel signal. It is sent to the canceler part 14.

The control channel signal canceller 14 is the same as the block shown in Fig. 12 described above, performs S / P conversion 141 on the determined control channel symbol, multiplies the spread code, and then spreads the frequency domain 142. Is done. Then, after performing the channel estimate multiplication 144 that multiplies the channel estimate obtained by the timing detection / channel estimation process 11 to each subcarrier component, the signal at the time of descramble accumulated in the memory 13 (canceller). Subtracted from (+ (148)), the received control signal is canceled.

In the traffic channel processing 20, the P / S conversion 205 is performed, demodulated by the demod 21, deinterleaved by the deinterleaver 22, and decoded by the decoder 23 to decode the traffic channel data. Output

(Example 10)

Fig. 15 is a block diagram showing the configuration of a receiver according to a tenth embodiment of the present invention, showing an embodiment of a receiver corresponding to the transmitter of the fifth embodiment. 16 is a block diagram of the control channel signal canceller unit of the present embodiment.

As shown in Fig. 15, in the receiver of the present embodiment, the received signal from which the guard interval is removed in the Remove GI 12 is subjected to S / P conversion 151, and then each subcarrier is performed by the FFT process 152. The signal is converted into components, and the signal at the time when the descramble 153 is performed is stored in the memory 13. After demodulating each subcarrier component in a demodulator (Demod) 156, a decoding process of a block code is performed in a decoder (157), and control channel data is obtained by performing P / S conversion (155).

In the configuration of Fig. 14 of the ninth embodiment described above, it is necessary to perform decoding processing of error correction codes on a frame basis, so that each OFDM symbol is converted to time series data by P / S conversion and then decoded on a frame basis. Although necessary, in the present embodiment, since the code length uses a block code equal to or less than the number of subcarriers, decoding processing can be performed in units of OFDM symbols. The decoded control channel data is sent to the control channel signal canceller 14, the control channel signal component is canceled from the received signal accumulated in the memory 13, and the P / S conversion 205 is performed in the traffic channel processing 20. The demodulator 21 demodulates, deinterleaves the deinterleaver 22, decodes the decoder 23, and outputs the traffic channel data.

As shown in FIG. 16, in the control channel signal canceller unit 14, the control channel decoded data once decoded is encoded again by the encoder (Enc) 145, and the subcarrier by the modulator (Mod) 146. After being modulated each time, a channel estimate multiplication 144 is performed to obtain a duplicate of the control channel signal. This is extracted from the descrambled signal stored in the memory 13 (+ (148)), and a canceller output signal is obtained.

(Example 11)

Fig. 17 is a flowchart of extracting a signal of a traffic channel only when it is found that the traffic channel includes information directed to the own station from the obtained control information. This flowchart applies to the block diagram of FIG. 13 or the block diagram of FIG. In the case of FIG. 13 and the case of FIG. 14, signals that are accumulated and canceled in the memory are different, but the flow of control is the same, and it is determined whether the information to the local station is included in the traffic channel of the received frame from the decoded control information. Subsequently, subsequent re-encoding / interleaving / modulation, control channel cancellation, and traffic channel reception processing are performed only when information directed to the own station is included.

Here, the signal is first received (step S1), and the guard interval is removed from the received signal (step S2). Each process of S / P conversion, FFT, and descramble is performed (step S3), and frequency domain despreading is performed (step S4). In addition, control channel demodulation, deinterleaving, and decoding processing are performed (step S5). 13, after the guard interval is removed in step S2, the received signal is stored in the memory (step S11). In addition, in the structure of FIG. 14, after descrambling is performed in step S3, the received signal is stored in the memory (step S12).

Next, from the decoded control information, it is judged whether or not traffic channel data directed to itself is included in the received frame (step S6). If the traffic channel data forwarded to itself is included, the control channel data is recoded, interleaved, and modulated (step S7). The control channel is canceled (step S8), and the traffic channel is processed (step S9). If the traffic channel before itself is not included in the received frame in step S6, the process ends (step S10).

(Example 12)

18 is also a flowchart for extracting a signal of a traffic channel only when it is found that the traffic channel includes information forwarded to the own station from the obtained control information. This flowchart applies to the block diagram of FIG. 13 or the block diagram of FIG. In the case of FIG. 13 and the case of FIG. 14, the signals accumulated in the memory and canceled are different from each other, but the flow of control is the same, and whether the information from the decoded control information includes the information forwarded to the local station in the traffic channel of the received frame. The determination proceeds to the next judgment only when information to the own station is included.

Here, the signal is first received (step S21), and the guard interval is removed from the received signal (step S22). Then, each process of S / P conversion, FFT and descramble is performed (step S23), and frequency domain despreading is performed (step S24). In addition, control channel demodulation, deinterleaving, and decoding processing are performed (step S25). 13, after the guard interval is removed in step S22, the received signal is stored in the memory (step S32). 14, after descrambling is performed in step S23, the received signal is stored in the memory (step S33).

Then, it is determined whether or not the traffic channel data forwarded to itself is included in the reception frame (step S26). If traffic channel data is included, the flow advances to step S27, which is the next judgment block, and if not, the process ends ( Step S31).

In step S27, it is determined whether the SNR is high enough. That is, whether or not to perform control channel cancellation by determining whether or not the traffic channel data can be output accurately without canceling the control channel signal from the communication channel state information measured by the channel estimator and the modulation / coding parameters included in the control channel. Determine whether or not. If the communication path quality is sufficiently high, the process of control channel recoding, interleave modulation, control channel cancellation is omitted, and the traffic channel is processed (step S30). In this case, the control channel canceler outputs the input from the memory to the traffic channel processing unit as it is. If the communication path quality is not high enough, control channel re-encoding, interleave, and modulation processing are performed (step S28), and control channel cancellation processing (step S29) is performed to perform traffic channel processing (step S30).

As described above, the system for multiplexing the control channel and the traffic channel has been described, but in the first to ninth embodiments, the traffic channel is traffic channel 1 for high-speed data communication, and the control channel is traffic channel for low-speed data communication. By substituting with 2, the embodiment in the case of multiplexing two traffic channels having different speeds can be used.

Regarding the configuration of the receiver, it is assumed that the signal transmitted from the transmitter as described in the first or fourth embodiment has been received via a wireless communication path, but the code multiplexed to the control channel as in the second or third embodiment. It is also possible to configure the signal using the same, and the claims of the present invention are not limited to the receiver corresponding to the control channel using a single code.

In the drawings of the embodiment, the OFCDM using frequency domain spreading has been described. However, it is apparent that the same effect can be obtained by using OFCDM performing two-dimensional spreading in the time domain and frequency domain or OFCDM spreading in the time domain. OFCDM described in the claims of the present invention is not limited to OFCDM using frequency domain spreading.

(Example 13)

19 is a block diagram of a transmitter according to Embodiment 13 of the present invention. In the drawings subsequent to FIG. 19, the same reference numerals are assigned to portions overlapping with FIGS.

In most wireless communication systems, in addition to traffic data exchanged between the user terminal and the other terminal, such as audio data, video data, and other packet data, control information exchanged with the system for operation on the wireless communication system, Control information indicative of the nature of the transmitted traffic data is communicated.

As shown in FIG. 19, in the present invention, traffic channel data and control channel data are separately encoded in the FEC encoders 100 and 104, interleaved in the interleavers 101 and 105, and modulated in the MODs 102 and 106. The traffic channel data symbol is converted into a traffic channel signal in the traffic channel signal generator 103, and the control channel symbol is converted into a control channel signal in the control channel signal generator 107. These signals are added as they are and transmitted.

20 is a block diagram of a traffic channel signal generator and a control channel signal generator of a transmitter according to Embodiment 13 of the present invention.

In the traffic channel signal generation unit 103 of FIG. 20A, after the S / P conversion 230a (serial-parallel conversion), the frequency domain spreading processing unit 201a transmits the traffic channel to be transmitted by a plurality of subcarriers. A frequency domain spreading process is performed by copying a symbol and multiplying the spread codes C _T0 , C _T1 , C _T2 , and C _T3 . After that, the cell-specific scrambling code is multiplied (scrambled), and an inverse fast Fourier transform process 231a (IFFT process) is performed. Further, P / S conversion 232a (parallel and serial conversion) is used as a time signal sequence, and the GI 240 is added by the Add GI 233a.

Similarly to the traffic channel signal generation section 103, the control channel signal generation section 107 of FIG. 20B also copies the control channel symbols so as to be transmitted by a plurality of subcarriers after the S / P conversion 230b. Then, the frequency domain spreading process 201b is performed by multiplying the spread codes C _C0 , C _C1 , C _C2 , and C _C3 . After that, the cell-specific scrambling code is multiplied (scramble 202b), and an inverse fast Fourier transform process (IFFT process 231b) is performed. In addition, P / S conversion 232b is used as a time signal sequence, and the GI 240 is provided by the Add GI 233b.

Here, the spreading codes C _T0 , C _T1 , C _T2 , and C _T3 for the traffic channel and the spreading codes C _C0 , C _C1 , C _C2 , and C _C3 for the control channel use codes that are not orthogonal to each other. . In this embodiment, although both the traffic channel signal and the control channel signal are spreading with a spreading rate of 4, the spreading may be performed at different spreading rates.

(Example 14)

Embodiment 14 of transmission signal generation using a method for generating a control channel different from Embodiment 13 will be described below.

This embodiment has the same configuration as that of the thirteenth embodiment shown in Figs. 19 and 20, but the configuration of the control channel signal generator 107 is different. The configuration of this part is shown in FIG.

The channel signal generation unit 300 shown in FIG. 21 distributes the control channel symbol by one symbol to the spread code by S / P conversion 230b. Each spreading code C _C0 , C _C1 , ..., C _CN-1 is a code in which code length N (= number of subcarriers) is orthogonal, and the spreading code is used to obtain a frequency-domain spreading 301 of spreading rate N. (Frequency domain spreading processing), and then MUX 302 performs code multiplexing. The cell-specific scrambling code is multiplied to perform inverse Fourier transform processing (IFFT processing 231b), and the P / S conversion 232b is used as a time signal sequence, and the GI 240 is added by Add GI 233b. Grant.

Here, the traffic channel spread codes C _T0 , C _T1 , C _T2 , C _T3 and the control channel spread codes C _C0 , C _C1 ,..., C _{CN -1} use codes that are not orthogonal to each other. . However, as described above, spreading codes for control channels are orthogonal to each other. In the above-described embodiment, only one traffic channel is generated, but when there are a plurality of traffic channels, spread codes for each traffic channel use orthogonal codes.

In the present embodiment, the diffusion rate can be increased as compared with the thirteenth embodiment. As the spreading rate increases, the code multiplexing is performed so that the transmission rate of the control channel does not change. Using the method of Embodiment 14, it is possible to average the interference from the traffic channel by increasing the spread rate. In addition, by spreading widely in the frequency domain, the frequency diversity effect can be increased.

(Example 15)

Embodiment 15 of transmission signal generation using a method for generating a control channel different from that of the thirteenth and thirteenth embodiments will be described below. This embodiment is common to the basic block diagrams shown in the traffic channel signal generating units of Figs. 19 and 20, and the control channel signal generating units of Fig. 20 have different configurations. 22 shows the configuration of the control channel signal generator 400 of this embodiment. The control channel signal generator 400 distributes the control channel symbol to the spread code by the S / P conversion 230b. After that, further S / P conversion is performed to perform frequency domain spreading (frequency domain spreading process 401), and code multiplexing is performed in MUX 302. Thereafter, the cell-specific scrambling code is multiplied (scrambled), and an inverse fast Fourier transform process (IFFT process 231b) is performed. In addition, after the time signal string is set by the P / S conversion 232b, the GI 240 is provided by the Add GI 233b.

If the number of subcarriers is large, the configuration becomes complicated in the fourteenth embodiment with the same diffusion rate and number of subcarriers. Therefore, the present embodiment in which the complexity is suppressed while increasing the spreading factor to some extent and obtaining the averaging effect and the diversity effect of the interference may be effective. This embodiment is an intermediate structure of the thirteenth and thirteenth embodiments in the above sense.

(Example 16)

In FIG. 19, for the sake of simplicity, the process of generating the traffic channel signal and the control channel signal in the time domain is completely separate. However, when the same scrambling code is used in the traffic channel and the control channel, the scrambling code is multiplied. The processing can be made common afterwards. FIG. 23 is a block diagram of a transmitter according to a sixteenth embodiment of the present invention, and FIG. 24 is a block diagram for explaining in detail the traffic channel control channel signal generation unit shown in FIG.

As shown in FIG. 23, the traffic channel data and the control channel data are separately encoded by the FEC encoders 100 and 104, interleaved by the interleavers 10 and 105, and modulated by the MODs 102 and 106, respectively. The symbol and the control channel symbol are input to the traffic channel control channel signal generator 500.

As shown in FIG. 24, the traffic channel control channel signal generation unit 500 performs the S / P conversion and then the traffic channel symbol that has undergone the frequency domain spreading process 201a, and the frequency domain after the S / P conversion. The control channel symbols that have undergone the spreading process 201b add corresponding subcarrier components, respectively, by the adder 501, multiply the cell-specific scrambling code (scramble 202b), and inverse Fourier transform processing (IFFT processing ( 231b)) and set as a time signal string by P / S conversion 232b, and then GI 240 is given by Add GI 233b.

(Example 17)

25 is a block diagram of a transmitter of the communication system according to the seventeenth embodiment of the present invention, and FIG. 26 is a block diagram of a traffic channel control channel signal generation unit of the present embodiment.

As shown in Fig. 25, in the transmitter of the present embodiment, the control channel data is input to the traffic channel control channel signal generation unit 700 as it is. Since the processing of the traffic channel data is the same as that of the sixteenth embodiment (shown in FIG. 23), repeated description is omitted.

In this embodiment, as shown in FIG. 26, in the traffic channel control channel signal generation unit 700, after performing S / P conversion 230a on the traffic channel symbol, the frequency domain spreading process 201a is performed. . Here, the control channel data subjected to S / P conversion 230b is block coded by the block encoder 701 (Enc) and modulated as each subcarrier component by the modulator 702 (MOD).

The block encoder 701 (Enc) is a block encoder that outputs n bits of codewords to k bits of input information bits. Here, n is preferably a divisor of the number N of subcarriers. Assuming n is a divisor of N and a modulation method of each subcarrier is BPSK, control channel data is serial-to-parallel converted in units of k · N / n bits in S / P conversion.

The encoding process is performed by the block encoders 701 (Enc) placed in parallel, and N bits are output. N bits are BPSK modulated as each subcarrier component and multiplexed with the traffic channel signal by the adder 501.

In FIG. 26, the processing of the traffic channel signal is the same as that of the sixteenth embodiment (refer to FIG. 24), and therefore, repeated description is omitted.

(Example 18)

27 is a block diagram showing the configuration of a receiver of a communication system according to an eighteenth embodiment of the present invention. The signal received by the receiver described in the present embodiment is assumed that the signal transmitted from the transmitter described in the thirteenth or sixteenth embodiment is a signal received via a wireless communication path.

First, timing detection and channel estimation are performed by the timing detection / channel estimation process 900 to obtain a timing and channel estimate value for cutting out a received signal for performing the FFT process 921a. From this channel estimate, the weighting coefficient Wi ^* (i = 0, 1 ... N-1) multiplied by each subcarrier after FFT processing 921a is determined. Here, the weighting factor Wi ^* is a complex airspace of the channel gain corresponding to the frequency component of each subcarrier in the communication path, but the method of determining the weighting factor Wi ^* is not limited to this method. The channel estimate is also used by the control channel signal canceller 905 to generate a duplicate of the control channel signal.

The received signal is removed from the Remove GI 901 and the GI 240 is first stored in the memory. First, demodulation of the control channel signal is performed. In the control channel signal processing unit 903, the control channel signal is subjected to OFCDM modulation in which frequency domain spreading is performed, so that the complex conjugate (C ^* _C0 , C ^* _C1 , C ^* _C2 , C ^* _C3) of the spreading code used for spreading is performed. And the weighting coefficient Wi ^* obtained in the timing detection / channel estimation process 900, frequency despreading process 923a is performed. Here, S / P conversion 920a, FFT processing 921a, descramble 922a, frequency domain despreading process 923a, and P / S conversion 924a are executed.

After the frequency domain despreading process 923a, control channel data is obtained through a demodulator 908 (Demod), a deinterleaver 909 (Deinterleaver), and a decoder 910 (Decoder).

After the frequency domain despreading, the determination unit 907 determines the symbol, and the control channel signal canceler unit 905 creates a duplicate of the control channel signal and stores the duplicated control signal from the received signal stored in the memory 904. The control channel signal component is removed. In the traffic channel signal processing unit 906, the OFCDM modulation for frequency domain spreading is performed on the signal from which the control channel signal component has been removed, that is, the complex channel (C ^* _T0) of the spreading code used for spreading. , C ^* _T1 , C ^* _T2 , C ^* _T3 ) and the frequency domain despreading process 923b is performed using the weighting coefficient Wi ^* obtained in the timing detection / channel estimation process. Here, S / P conversion 920b, FFT processing 921b, descramble 922b, frequency domain despreading process 923b, and P / S conversion 924b are performed. The demodulator 911 (Demod), the deinterleaver 912 (Deinterleaver), and the decoder 913 (Decoder) perform error correction decoding to obtain traffic channel data.

28 is a configuration diagram showing a detailed configuration of a control channel signal canceller unit. After the S / P conversion 930 is performed on the control channel symbol determined by the determination unit 907 shown in FIG. 27, similarly to the control channel signal generation unit 107 of FIG. 20, the control channel symbol is changed. Copy to be transmitted by a plurality of subcarriers, multiply spread codes C _C0 , C _C1 , C _C2 , C _C3 to perform frequency domain spreading (frequency domain spreading processing), and also multiply cell-specific scrambling codes (Scramble). Here, after multiplying the channel estimate obtained by the channel estimator 900 to each subcarrier component (channel multiplication value), an inverse fast Fourier transform process (IFFT process 932) and P / S transform 933 are performed. Obtain a replica of the time signal of the control channel signal. By subtracting this duplicated signal by the adder 934 from the received signal stored in the memory, a received signal in which the control channel signal is canceled is obtained.

(Example 19)

29 is a block diagram showing the configuration of a receiver according to a nineteenth embodiment of the present invention.

In FIG. 27 and FIG. 28, an embodiment in which the control channel signal is canceled from the received signal by the signal in the time domain has been described. However, as shown in FIGS. 29 and 30, the canceling is performed for each subcarrier in the frequency domain. Do.

In this embodiment, a frequency despreading process is performed by the traffic channel signal processing unit 952 for the received signal from which the guard interval has been removed in the Remove GI 950. Here, the received signal is subjected to S / P conversion 970, FFT processing 971 is performed, and each signal is converted into subcarrier components, and the signal at the time when the descramble 972 is performed is stored in the memory 956. The control channel signal is subjected to the frequency domain despreading process 973 and the P / S conversion 974 as it is, and then the symbol determination processing 955 is performed (determination 955). The control channel signal canceller unit 957 cancels the control channel signal in the frequency domain. After the frequency domain despreading process 959, the traffic channel signal processing unit 1 958 performs P / S conversion 960, demodulates in the Demod 961, deinterleaves in the deinterleaver 962, and decodes the decoder. The traffic channel data is output via the Decoder 962. In addition, repeated description of the function similar to FIG. 27 is abbreviate | omitted.

30 is a detailed block diagram of the control channel signal canceller unit 957 illustrated in FIG. 29.

Here, S / P conversion 98 is performed on the determined control channel symbol, and frequency-domain spreading is performed by multiplying spread codes C _C0 , C _C1 , C _C2 , C _C3 . After multiplying the channel estimate obtained by the timing detection / channel estimation process by each subcarrier component, the control channel signal is subtracted from the descrambled signal (canceller) stored in the memory 956. Obtains the canceled received signal.

(Example 20)

31 is a block diagram showing the configuration of a receiver according to a twentieth embodiment of the present invention.

First, timing detection and channel estimation are performed by the timing detection / channel estimation process 1010, and the timing and channel estimation value which cut out the received signal for performing FFT processing are calculated | required. From this channel estimate, the weighting coefficient multiplied by each subcarrier after FFT processing 1016 is determined.

In the received signal, the guard interval is removed in the Remove GI 1011, and once accumulated in the memory 1012, demodulation of the control channel is performed first. In the control channel data signal processing section 1014, since the control channel signal is subjected to OFCDM modulation in which frequency domain spreading is performed, complex conjugated domains (C ^* _C0 , C ^* _C1 , C ^* _C2 , C ^*) of spreading codes used for spreading are performed. _C3 ) and the frequency domain despreading process 1018 is performed using the weighting coefficient obtained in the timing detection / channel estimation process 1010. Here, S / P conversion 1015, FFT processing 1016, descramble 1017, frequency domain despreading process 1018, and P / S conversion 1019 are executed.

After the frequency despreading, control channel data is obtained through a demodulator 1020, a deinterleaver 1021, and a decoder 1022.

In the present embodiment, the control channel data decoded by the decoder 1022 is again encoded by the FEC encoder 1023, interleaved by the interleaver 1025, and modulated by the MOD 1026 to cancel the control channel signal. It is sent to the part 1013.

The control channel signal canceler 1013 is the same as the block of FIG. 28 described above. Here, Fig. 28 is usefully explained.

First, after S / P conversion 930, the control channel symbols are copied in the copying units 931a and b so as to be transmitted by a plurality of subcarriers, and the spread codes C _C0 , C _C1 , C _C2 and C _C3 ), Frequency-domain spreading is performed (frequency-domain spreading processing), and the cell-specific scrambling code is multiplied (scrambled). Here, after multiplying the channel estimate obtained by the channel estimator 1010 to each subcarrier component (channel multiplication value), an inverse Fourier transform process (IFFT process) 932 and P / S transform 933 are performed. A replica of the time signal of the control channel signal is obtained. The subtractor 934 subtracts this duplicated signal from the received signal stored in the memory to obtain a received signal from which the control channel signal has been canceled.

Then, the generated received signal is subjected to OFCDM demodulation processing by the traffic channel signal processing unit 1027. Here, S / P conversion 1028, FFT processing 1029, descramble 1030, frequency domain despreading process 1031, and P / S conversion 1032 are performed. In addition, error correction decoding is performed by the demodulator 1033, the deinterleaver 1034, and the decoder 1035 to obtain traffic channel data.

(Example 21)

32 is a block diagram showing a configuration of a receiver according to Embodiment 21 of the present invention. The received signal from which the guard interval has been removed in the Remove GI 1110 is subjected to frequency despreading by the control channel signal processing unit 1112, but here, the received signal is subjected to S / P conversion 1113 to perform FFT processing. (1114) is converted to each subcarrier component, and the signal at the time when the descramble 1115 is performed is stored in the memory 1124. The control channel signal is subjected to frequency domain despreading process 1116 and P / S conversion 1117 as it is.

After the control channel data signal processing unit 1112, control channel data is obtained via a demodulator 1118, a deinterleaver 1119, and a decoder 1120.

In the present embodiment, the control channel data once decoded by the decoder 1120 is encoded by the FEC encoder 1121, interleaved by the interleaver 1122, and modulated by the MOD 1123, and the control channel signal. It is sent to the cancellation unit 1125.

The control channel signal canceller 1125 is the same as the block of FIG. 30 described above. Here, it demonstrates using FIG.

The S / P conversion 980 is performed on the control channel symbol modulated by the MOD 1123, and the frequency domain spreading process is performed by multiplying the spread codes C _C0 , C _C1 , C _C2 , and C _C3 . After the channel estimate multiplied by each subcarrier component is multiplied by the channel estimate obtained by the timing detection / channel estimation process, the control channel signal is canceled by subtracting it from the descrambled signal (canceller) stored in the memory. Get the received signal.

After the frequency domain despreading process 1127, the traffic channel processing unit 1126 performs P / S conversion 1128, demodulates in the Demod 1129, deinterleaves the deinterleaver 1130, and then decodes the decoder. Decode in 1113 to output traffic channel data.

(Example 22)

33 is a block diagram showing the configuration of a receiver according to a twenty-second embodiment of the present invention, and is a block diagram showing the configuration of a receiver corresponding to the transmitter according to the seventeenth embodiment. 34 is a block diagram of the control channel signal canceller unit of the present embodiment.

As illustrated in FIG. 33, in the receiver according to the present embodiment, the received signal from which the guard interval is removed in the Remove GI 1210 is subjected to S / P conversion 1213 by the control channel data signal processing unit 1212. The FFT process 1214 converts the signals into subcarrier components and stores the signals at the time when the descramble 1215 is performed in the memory 1217. Then, after demodulating each subcarrier component in a demodulator (Demod), the decoder (Decoder) performs decoding processing of the block code, and control channel data is obtained by performing P / S conversion (1216).

In the configuration of the twenty-first embodiment shown in FIG. 32 described above, since the error correction code is decoded in units of frames, each OFDM symbol is decoded into time-series data by P / S conversion and decoded in units of frames. Although necessary, in the present embodiment, since the code length uses a block code equal to or less than the number of subcarriers, decoding processing can be performed in units of OFDM symbols. The decoded control channel data is sent to the control channel signal canceller 1212, the control channel signal component is canceled from the received signal accumulated in the memory 1217, and the frequency channel despreading process is performed by the traffic channel processing 1219. After 1220, P / S conversion 1221 is performed, demodulated at 1222, deinterleaved at deinterleaver 1223, and decoded at decoder 1224 to obtain traffic channel data.

As shown in FIG. 34, in the control channel signal canceller unit 1218, the control channel decoded data once decoded is encoded again by the encoder (Enc) 1225, and modulated for each subcarrier by the modulator (Mod) 1226. After that, the channel estimate multiplication is performed to obtain a duplicate of the control channel signal. This is subtracted from the descrambled signal stored in the memory 1217 to obtain a canceller output signal.

(Example 23)

35 is a block diagram of a control channel signal generator and a traffic channel signal generator of a transmitter according to the twenty-third embodiment;

In this embodiment, the control channel signal generation unit 103 and the traffic channel signal generation unit 107 of the thirteenth embodiment have a configuration in which an orthogonal code generation unit 108 representing the features of this embodiment is added. This embodiment has the same configuration as the thirteenth embodiment except that the spreading code (code) switching function is provided. Naturally, in the case of the thirteenth embodiment, a code generation unit exists, but since the control channel signal and the traffic channel signal use only codes that are not orthogonal, the description is omitted.

The control channel signal generator 103 and the traffic channel signal generator 107 in FIG. 35 have the same configuration as those in the thirteenth embodiment, and thus description thereof is omitted. The orthogonal code generator 108 switches between orthogonal code generator 1 109, orthogonal code generator 2 110, and orthogonal code generator 1 109 and orthogonal code generator 2 110 that generate a plurality of orthogonal codes. It consists of a code switch 111. However, the code generated from orthogonal code generator 1 109 and the code generated from orthogonal code generator 2 110 are non-orthogonal to each other.

The code used for the traffic channel signal uses only the code generated in orthogonal code generator 1 109. In addition, the code used for the control channel signal, when the quality of the communication path is good, by switching the code switch 111 to the orthogonal code generator 2 (110) side, the code generated by the orthogonal code generator 2 (110) If the quality of the communication path is poor, the code generated by the orthogonal code generator 1 109 is used by switching the code switch 111 to the orthogonal code generator 1 109 side. If there are a plurality of control channels or traffic channels, for example, the selection of the orthogonal code and the non-orthogonal code is performed by the channel via the worst communication channel, or the average value of the levels of the plurality of channels. You can judge.

In the above, the orthogonal and non-orthogonal determinations are made based on the quality of the communication path. However, if the code generated by the orthogonal code generator 1 109 is sufficiently satisfactory as the code used for the control channel signal, the orthogonal code generator 1 ( It is also possible to use the code generated in the orthogonal code generator 2 110 by switching the code switch 111 to the orthogonal code generator 2 110 when the code generated in 109 is insufficient. In this case, however, if the non-orthogonal code is used, the reception quality deteriorates as compared with the use of the orthogonal code. Therefore, it is necessary to transmit with a slightly higher transmission level than when using the orthogonal code.

In this embodiment, only the control channel signal is configured to switch the orthogonal code generators 1 109 and 2 (110), but only the traffic channel signal is configured to switch the orthogonal code generators 1 and 2, The control channel signal and the traffic channel signal may be configured such that the orthogonal code generator 1 109 and the orthogonal code generator 2 110 can be switched. For example, this is valid when a code of a control channel is to be fixed.

From the above, the optimum code assignment can be made according to the quality of the communication path and the number of codes in use.

(Example 24)

36 is a block diagram showing the construction of a receiver according to a twenty-fourth embodiment of the present invention.

In the present embodiment, it is assumed that the received signal is a signal transmitted from the transmitter as described in the twenty-fourth embodiment (see Fig. 35) via a wireless communication path. In the present embodiment, as a spreading code of the control channel signal, a code that is not orthogonal to the spreading code used in the traffic channel signal when the quality of the communication channel is good, and the quality of the communication path is poor, The configuration of the receiver in the case of receiving a signal when an orthogonal code is used is shown. For this reason, in particular, the receiver does not have the control channel signal canceller described above.

First, timing detection and channel estimation are performed by the timing detection / channel estimation process 1300 to obtain timing and channel estimate values for cutting out a received signal for performing the FFT process 1330. In the received signal, the guard interval is removed in the Remove GI 1310, and the S / P conversion 1320 and the FFT process 1330 are performed. Thereafter, the control channel and the traffic channel are separately detected by the control channel data signal processor 2 (1340) and the traffic data signal processor 2 (1360).

Since the control channel signal is subjected to OFCDM modulation for frequency domain spreading, the complex convolution (C ^* _C0 , C ^* _C1 , C ^* _C2 , C ^* _C3 ) of the spreading code used for spreading and the timing detection / channel estimation process are obtained. The frequency despreading process is performed using the weighting coefficient. Here, descramble, frequency domain despreading, and P / S conversion are performed. Here, the complex conjugate (C ^* _C0 , C ^* _C1 , C ^* _C2 , C ^* _C3 ) of the spreading code used for spreading is output by the code switch. The code switcher switches to orthogonal code generator 1 when the control channel is spread by a code orthogonal to the traffic channel, and to orthogonal code generator 2 when it is spread by a non-orthogonal code. After the frequency despreading process, control channel data is obtained via a demodulator (Demod) 1361, a deinterleaver (1362), and a decoder (1363).

Since the traffic channel signal is subjected to OFCDM modulation in which frequency domain spreading is similarly performed, the complex conjugate (C ^* _T0 , C ^* _T1 , C ^* _T2 , C ^* _T3 ) and timing detection / channel of the spreading code used for spreading are performed. The frequency domain despreading process is performed using the weighting coefficient obtained in the estimation process. Here, descramble, frequency domain despreading, and P / S conversion are performed. Here, the complex conjugate (C ^* _T0 , C ^* _T1 , C ^* _T2 , C ^* _T3 ) of the spreading code used for spreading is output by the orthogonal code generator 1. After the frequency domain despreading process, the traffic channel data is obtained through a demodulator (13mod), a deinterleaver (1365), and a decoder (1366).

In the above receiver configuration, if the descramble code is the same in the control channel and the traffic channel, it is possible to commonize the descramble.

(Example 25)

37 is a block diagram showing the construction of a receiver according to a twenty-fifth embodiment of the invention.

In the present embodiment, it is assumed that the received signal is a signal transmitted from the transmitter as described in the twenty-fourth embodiment (see Fig. 35) received via a wireless communication path. In the present embodiment, unlike the twenty-fourth embodiment, the receiver has a canceller. As a result, even if the spreading code of the control channel is not orthogonal to the spreading code of the traffic channel, the canceler can demodulate the traffic channel signal after canceling the control channel signal from the received signal. It becomes possible.

First, timing detection and channel estimation are performed by the timing detection / channel estimation process 1400 to obtain a timing and a channel estimate value for cutting out a received signal for performing the FFT process. From this channel estimate, the weighting coefficient multiplied by each subcarrier after FFT processing is determined.

The received signal is removed from the guard GI 1410, the guard interval is first stored in the memory 1420, and the control channel data signal processing unit 1430 first detects the control channel signal. Since the control channel signal is subjected to OFCDM modulation in which frequency-domain spreading is performed, the complex convolution (C ^* _C0 , C ^* _C1 , C ^* _C2 , C ^* _C3 ) of the spreading code used for spreading and timing detection / channel estimation processing are performed. The despreading process is performed using the obtained weighting factor. Here, S / P conversion, FFT processing, descramble, frequency domain despreading, and P / S conversion are performed. Here, the orthogonal code generation unit 1440 is the same as in the twenty-fourth embodiment, and the complex conjugate (C ^* _C0 , C ^* _C1 , C ^* _C2 , C ^* _C3 ) of the spreading code used for spreading is a code switcher. Is output by After the despreading process by the control channel signal processing unit 1430, control channel data is obtained through a demodulator (1441), a deinterleaver (1442), and a decoder (1443).

Next, detection of the traffic channel by the traffic channel signal processing unit 1484 will be described. If the spreading code of the received control channel is a code orthogonal to the spreading code of the traffic channel, the control channel canceler 1447 outputs the input from the memory 1420 to the traffic channel signal processing unit 1482 as it is. Thus, the traffic channel is detected (demodulated) without canceling the control channel. That is, OFCDM demodulation processing of the traffic channel is performed. Here, S / P conversion, FFT processing, descramble, frequency domain despreading, and P / S conversion are performed. Then, error correction decoding is performed by a demodulator (Demod), a deinterleaver and a decoder to obtain traffic channel data.

If the spreading code of the received control channel is a code that is not orthogonal to the spreading code of the traffic channel, the control channel signal is canceled from the received signal to demodulate the traffic channel.

That is, the decoded control channel data is encoded by the FEC encoder 1444 again, interleaved by the interleaver 1445, modulated by the MOD 1446, and sent to the control channel signal canceller 1447. The control channel signal canceller 1447 is the same as the block of Fig. 28 already described, and after performing S / P conversion, copy the control channel symbol to be transmitted by a plurality of subcarriers, and spread code C _C0 , C Frequency domain spreading is performed by multiplying _C1 , C _C2 , C _C3 (frequency domain spreading process (1), and a cell-specific scrambling code is also multiplied (scrambled). Here, the channel estimate obtained by the channel estimating section is obtained. After multiplying each subcarrier component (multiplying the channel estimate), inverse Fourier transform processing (IFFT processing) and P / S conversion are performed to obtain a replica of the time signal of the control channel signal. By subtracting from the received signal, a received signal (traffic channel signal) from which the control channel signal has been canceled is obtained.

As described above, the traffic channel demodulation process is performed to obtain traffic channel data from the received signal.

In the present embodiment, the control channel signal is reproduced from the control channel data as a method of canceling the control channel signal. However, the control channel signal may be reproduced from the control channel symbol before Demod 1442. In addition, in this embodiment, cancellation is performed in the time domain before S / P, but it is also possible to cancel each subcarrier in the frequency domain after the FFT processing.

Next, the operation of the receiver (refer to the block diagrams in FIGS. 31 and 32) according to the above-described embodiments 20 and 21 will be described below using the flowchart shown in FIG. 38.

FIG. 38 is a flowchart showing a process of extracting a signal of a traffic channel when it is found that the traffic channel includes information directed to the own station from the obtained control information.

In the case of FIG. 31 and the case of FIG. 32, the signals accumulated in the memory 1012 or 1124 and canceled are different, but the flow of control is the same. That is, it is determined from the decoded control information whether the traffic channel of the received frame includes information forwarded to the own station, and subsequent re-encoding, interleaving, modulation, control channel cancellation, and traffic channel only when the information forwarded to the own station is included. Receive processing is performed.

Here, first, a signal is received (step S0), and the guard interval is removed by the Remove GI from the received signal. Then, S / P conversion, FFT processing, and descrambling processing are performed (step S2), and frequency domain despreading processing is performed (step S3). In addition, control channel demodulation, deinterleaving, and decoding processing are performed (step S4). Here, in the case of the receiving device having the configuration shown in FIG. 31, after the guard interval is removed, the received signal is stored in the memory 1012. In addition, in the reception device having the configuration shown in FIG. 32, after the descramble 1115 is performed, the received signal is stored in the memory 1124.

Subsequently, from the decoded control channel information, it is judged whether or not traffic channel data directed to itself is included in the received frame (step S5). If traffic channel data forwarded to itself is included (step S5; YES), control channel data is recoded, interleaved, and modulated (step S6). Then, the control channel is canceled and the traffic channel is processed (step S8). If the traffic channel before itself is not included in the received frame (step S5; NO), the processing ends.

Next, in the operation of the receiver (refer to the block diagrams in FIGS. 31 and 32) according to the above-described embodiments 20 and 21, the determination operation of whether or not to control channel cancellation is performed by the value of the SN ratio. The operation will be described below using the flowchart shown in FIG. 39.

39 is also a flowchart for extracting a signal of a traffic channel only when it is found that the traffic channel includes information forwarded to the own station from the obtained control channel information. In the case of FIG. 31 and the case of FIG. 32, the signals accumulated in the memory and canceled are different from each other, but the flow of control is the same, and whether the information from the decoded control information includes the information forwarded to the own station from the decoded control information. The determination proceeds to the next judgment only when information to the own station is included.

In this case, first, a scene injury is received (step S10), and the guard interval is removed from the received signal (step S11). Then, each process of S / P conversion, FFT, and descramble is performed (step S12), and frequency domain despreading is performed (step S13). In addition, control channel demodulation, deinterleaving, and decoding processing are performed (step S14). Here, similarly to the flow shown in FIG. 38, in the case of the configuration of FIG. 31, after the guard interval is removed, the received signal is stored in the memory. In addition, in the configuration of FIG. 32, after descrambling is performed, the received signal is stored in the memory.

Then, it is determined whether or not the traffic channel data forwarded to itself is included in the reception frame, and the process ends if the traffic channel data is not included.

If traffic channel data is included, it is determined whether the SNR is high enough (step S16). That is, whether or not to perform control channel cancellation by determining whether or not the traffic channel data can be output accurately without canceling the control channel signal from the communication channel state information measured by the channel estimator and the modulation / coding parameters included in the control channel. Determine whether or not. If the communication path quality is sufficiently high (step S16; YES), the control channel re-encoding / interleaving / modulation and control channel cancellation processing are omitted, and the traffic channel processing is performed (step S19). In this case, the control channel canceler outputs the input from the memory to the traffic channel processing unit as it is. If the communication path quality is not high enough (step S16; NO), control channel recoding, interleaving, and modulation processing are performed (step S17), and control channel cancellation processing is performed (step S18). (Step S19).

Next, a case in which the control channel spreading code is distinguished from a code orthogonal to a traffic channel spreading code according to the quality of the communication channel is used from the transmitter as described in the twenty-third embodiment. It demonstrates using the operation flow shown in FIG. 40 in the receiving device shown in FIG. 37 which receives a transmitted signal.

38 and 39, like FIG. 38 and FIG. 39, are the flowcharts which extract the signal of a traffic channel only when it turns out that the traffic channel contains the information forwarded to the own station from the obtained control information.

First, a signal is received (step S20), and a guard interval is removed from the received signal (step S21). Here, the signal from which the guard interval has been removed is stored in the memory. Each process of S / P conversion, FFT, and descramble is performed, and frequency domain despreading is performed (step S23). Here, if the spreading code of the control channel is orthogonal to the spreading code of the traffic channel, the despreading is performed by the code output from the orthogonal code generator 1 if the spreading code of the control channel is orthogonal. Thereafter, control channel demodulation, deinterleaving, and decoding processing are performed (step S24).

Then, it is judged whether or not the traffic channel data directed to itself is included in the reception frame (step S25). If the traffic channel data is not included, the process ends (step S25; "No"). If traffic channel data is included (step S25; YES), the flow advances to the next step, and it is determined whether the spreading code of the control channel signal is a code orthogonal to the spreading code of the traffic channel or not. It determines (step S26).

If the code is orthogonal (step S26), if an orthogonal code is used (step S26; YES), it is determined whether the SNR is sufficiently high (step S27). That is, when the orthogonal code is used (step S26; YES), even if the control channel signal is not canceled from the communication channel state information measured by the channel estimating unit, the modulation / coding parameters included in the control channel, and so on, It is judged whether or not output is possible correctly, and whether or not control channel cancellation is to be performed. Specifically, if the measured SNR value is greater than the threshold value T _orthogonal of the SNR for determining whether or not to cancel the control channel when the orthogonal code is used, and if it is large (step S27; YES), Control channel re-encoding, interleave modulation, control channel cancellation processing is omitted, and the traffic channel processing is performed. In this case, the control channel canceler outputs the input from the memory to the traffic channel processing unit as it is. If not large (step S27; NO), control channel re-encoding, interleaving, and modulation processing are performed, and control channel cancellation processing is further performed to perform traffic channel processing.

If the code is not orthogonal (step S26; "No"), it is determined whether the SNR is sufficiently high when the code that is not orthogonal is used (step S28). That is, in the case of using non-orthogonal codes, it is determined whether the traffic channel data can be output correctly without canceling the control channel signal from the channel state information measured by the channel estimator and the modulation / coding parameters included in the control channel. It is determined whether or not control channel cancellation is to be performed. Specifically, if the measured SNR value is larger than the threshold T _{non-orthogonal} of the SNR that determines whether or not to cancel the control channel when a code that is not orthogonal is used, and is large (step S28; "Yes"), the control channel re-encoding / interleaving / modulation and control channel cancellation processing are omitted, and the traffic channel processing is performed. In this case, the control channel canceler outputs the input from the memory to the traffic channel processing unit as it is. If not large (step S28; NO), control channel re-encoding, interleaving, modulation processing are performed, control channel cancellation processing is further performed, and traffic channel processing is performed.

In general, when a non-orthogonal code is used, the reception quality is inferior to that of an orthogonal code. Therefore, it is necessary to set the above threshold T _{non - orthogonal} to be larger than the threshold T _orthogonal .

By using the method of the present embodiment, it becomes possible to optimally receive the quality of the communication path in accordance with the orthogonal and non-orthogonal codes.

In a system for multiplexing and transmitting the control channel and the traffic channel, the spreading code C _C for the control channel and the spreading code C _T for the traffic channel are different. However, C _C and C _T may be the same, and in this case, the scrambling codes may be different. For example, as the first method, there is a method of using a cell-specific control channel scramble code and a cell-specific traffic channel scramble code. As a second method, there is a method using a cell common control channel scramble code and a cell specific traffic channel scramble code. In the case where the cell common control channel scramble code is used, the cell can be distinguished by the control channel spreading code.

As described above, the system for multiplexing the control channel and the traffic channel has been described. However, in the above embodiments 13 to 25, the traffic channel communicates the low-speed data in the control channel to the traffic channel 1 in which the high-speed data is communicated in the traffic channel. By substituting with 2, the embodiment in the case of multiplexing two traffic channels having different speeds can be used.

Regarding the configuration of the receiver, it is assumed that the signal transmitted from the transmitter as described in the thirteenth, sixteenth, or twenty-third embodiment is received via a wireless communication channel, but the code is assigned to the control channel as in the fourteenth or fifteenth embodiment. It is possible to similarly configure the signal using multiplexing, and the scope of the claims of the present invention is not limited to the receiver corresponding to the control channel using a single code.

In addition, as shown in the drawings used for the explanation in the above embodiment, although both the control channel signal and the traffic channel signal have been described using OFCDM using frequency domain spreading, OFCDM which performs two-dimensional spreading in the time domain and the frequency domain, It is obvious that the same effect can be obtained even by using OFCDM which performs time domain spreading, and is not limited to OFCDM using frequency domain spreading.

As described above, the data communication system, the transmission device, and the reception device according to the present invention are useful for a wireless communication system that simultaneously transmits high-speed data communication and low-speed data or control data, and improves the effective use of frequencies and the flexibility of multiplexing. This is excellent.

Claims (57)

A communication system using Orthogonal Frequency Division Multiplexing (OFDM) technology, comprising: a traffic channel for transmitting traffic data, a control channel for transmitting control data, a traffic channel signal generated using OFDM modulation, and the traffic channel signal And a transmission signal is generated by multiplexing a control channel signal generated using a signal that is not orthogonal to any of time, frequency, and code. The method of claim 1, And the control channel signal is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions of the OFDM modulated traffic channel signal. The method of claim 1, And the control channel signal is a signal encoded by a low rate block code, and the code word is a signal configured to be transmitted using a plurality of subcarriers of a single OFDM symbol. The method of claim 1, On the receiving station side, a copy of the control channel signal multiplexed to the received signal is generated from a received symbol obtained by receiving a signal multiplexed with the traffic channel and the control channel, demodulating the control channel to determine a signal point, And demodulating the traffic channel after removing a control channel signal component from a received signal. The method of claim 1, The data of the control channel is error corrected and coded, and on the receiving station side, a control multiplexed to a received signal from control channel data obtained by receiving a signal multiplexed with the traffic channel and the control channel, and demodulating and decoding the control channel. And demodulating the traffic channel after generating a duplicate of the channel signal and removing the control channel signal component from the received signal. The method of claim 1, The data of the control channel is error correction coded, and the data of the control channel includes destination information of the traffic channel transmitted at or after that time. On the receiving station side, the traffic channel and the control channel Receiving the multiplexed signal, demodulating and decoding the control channel to extract control channel data, and determining whether the traffic channel includes information forwarded to the own station from control information obtained in the past or at that time; If the channel contains information forwarded to the own station, a duplicate of the control channel signal multiplexed to the received signal is generated from the extracted control channel data, and after removing the control channel signal component from the received signal, demodulating the traffic channel. A communication system, characterized in that for performing. A communication system using Orthogonal Frequency Division Multiplexing (OFDM) technology, comprising: traffic channel 1 for transmitting high-speed traffic data, and traffic channel 2 for transmitting low-speed traffic data, wherein traffic channel 1 is generated using OFDM modulation. And a transmission signal is generated by multiplexing a signal of traffic channel 2 generated by using a signal of the traffic channel 1 and a signal that is not orthogonal to any of time, frequency, and code with respect to the signal of the traffic channel 1. . The method of claim 7, wherein And said traffic channel 2 signal is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions of said OFDM modulated traffic channel 1 signal. The method of claim 7, wherein The signal of the traffic channel 2 is a signal encoded by a low rate block code, and the code word is a signal configured to be transmitted using a plurality of subcarriers of a single OFDM symbol. The method of claim 7, wherein At the receiving station side, the traffic channel multiplexed to the received signal from the symbol of traffic channel 2 obtained by receiving a signal multiplexed by the traffic channel 1 and the traffic channel 2, and demodulating the traffic channel 2 to determine a signal point. Demodulating the traffic channel 1 after generating a duplicate of the signal of 2 and removing the signal component of the traffic channel 2 from the received signal. The method of claim 7, wherein The data of the traffic channel 2 is error corrected coded, and on the receiving station side, from the data of the traffic channel 2 obtained by receiving a signal in which the traffic channel 1 and the traffic channel 2 are multiplexed and demodulating and decoding the traffic channel 2 And demodulating the traffic channel 1 after generating a duplicate of the signal of the traffic channel 2 multiplexed with the received signal and removing the signal component of the traffic channel 2 from the received signal. A transmission apparatus using orthogonal frequency division multiplexing (OFDM) modulation, comprising: means for OFDM-modulating traffic channel data to generate a traffic channel signal, and a signal that is not orthogonal to any of time, frequency, or code with respect to the traffic channel signal; And means for generating a control channel signal from the control channel data using means, and means for generating a transmission signal by multiplexing the traffic channel signal and the control channel signal. The method of claim 12, The control channel signal generating means includes means for spreading a control channel symbol for transmitting control channel data over a plurality of subcarriers, a plurality of OFDM symbols, or both regions of the OFDM modulated traffic channel signal. A transmitting device, characterized in that. The method of claim 12, The control channel signal generating means includes encoding means by a low rate block code, and means for arranging the codeword to be transmitted using a plurality of subcarriers of a single OFDM symbol. A receiving apparatus for receiving a signal transmitted from the transmitting apparatus of claim 12, comprising: means for generating a duplicate of the control channel signal multiplexed with a received signal from a received symbol obtained by demodulating the control channel to determine a signal point; And means for removing the control channel signal component from the received signal. A receiving device for receiving a signal transmitted from the transmitting device of claim 12, wherein the control channel data is error corrected and coded, and the control channel signal multiplexed with a received signal from control channel data obtained by demodulating and decoding the control channel. And means for generating a replica of the means and for removing the control channel signal component from the received signal. A receiving device for receiving a signal transmitted from the transmitting device of claim 12, wherein the data of the control channel is error corrected and coded, and has a means for demodulating and decoding the control channel to extract control channel data. It is determined whether the traffic channel includes information forwarded to the local station from the control information obtained at. In the case where the traffic channel includes information forwarded to the local station, the control multiplexed to the received signal from the extracted control channel data. And demodulating the traffic channel after generating a duplicate of the channel signal and removing the control channel signal component from the received signal. A receiving apparatus for receiving a signal transmitted from the transmitting apparatus of claim 12, comprising: receiving a signal in which the traffic channel and the control channel are multiplexed, and replicating the control channel from a control channel symbol obtained by demodulating and determining the control channel. A canceling function 1 for generating and removing the control channel signal component from the received signal, and from the control channel data obtained by receiving a signal multiplexed with the traffic channel and the control channel and demodulating and decoding the control channel. Has a canceling function 2 for generating a duplicate of the multiplexed control channel and removes the control channel signal component from the received signal, and depending on the quality of the communication path, any one of the canceling function 1, the canceling function 2, and no canceling Select and perform demodulation of the traffic channel. Value. A receiving device for receiving a signal transmitted from the transmitting device of claim 12, wherein the traffic channel and the control channel are multiplexed, and the multiplexed to the received signal from a control channel symbol obtained by demodulating and determining the control channel. A control obtained by generating a duplicate of the control channel signal, canceling the control channel signal component from the received signal, receiving a signal multiplexed with the traffic channel and the control channel, and demodulating and decoding the control channel It has only one canceling function of either of the two canceling functions of the canceling function 2, which generates a duplicate of the control channel multiplexed into the received signal from the channel data and removes the control channel signal component from the received signal, By selecting either with or without cancellation of the traffic A receiver for demodulating a channel. A transmission apparatus using orthogonal frequency division multiplexing (OFDM) modulation, comprising: means for OFDM-modulating the data of traffic channel 1 to generate a signal of traffic channel 1, and a signal of time, frequency, or code for the signal of traffic channel 1; Means for generating a signal of traffic channel 2 using a signal not orthogonal to the signal; and means for generating a transmission signal by multiplexing the signal of traffic channel 1 and the signal of traffic channel 2; Device. The method of claim 20, The signal generating means of the traffic channel 2 includes means for spreading a symbol for transmitting the traffic channel 2 over a plurality of subcarriers or a plurality of OFDM symbols, or both regions of the signal of the OFDM modulated traffic channel 1. Transmission apparatus comprising a. The method of claim 20, The signal generating means of the traffic channel 2 includes encoding means based on a low rate block code, and means for arranging the code word to be transmitted using a plurality of subcarriers of a single OFDM symbol. . A reception device for receiving a signal transmitted from the transmission device of claim 20, wherein the traffic channel 2 signal is multiplexed to a received signal from a symbol of traffic channel 2 obtained by demodulating the traffic channel 2 to determine a signal point. And means for generating a signal component of the traffic channel 2 from the received signal. A reception device for receiving a signal transmitted from the transmission device of claim 20, wherein the data of the traffic channel 2 is error corrected and multiplexed to the received signal from the data of the traffic channel 2 obtained by demodulating and decoding the traffic channel 2. Means for replicating the traffic signal of the traffic channel 2, and means for removing the signal component of the traffic channel 2 from the received signal. A receiving device for receiving a signal transmitted from the transmitting device of claim 20, comprising: generating a duplicate of the signal of the traffic channel 2 multiplexed with a received signal from a symbol of the traffic channel 2 obtained by demodulating and determining the traffic channel 2, and receiving A cancellation function 1 for removing the signal component of the traffic channel 2 from the signal, and a copy of the signal of the traffic channel 2 multiplexed with the received signal from the data of the traffic channel 2 obtained by demodulating and decoding the traffic channel 2, Has a canceling function 2 for removing the signal component of the traffic channel 2 from the received signal, and selects one of the canceling function 1, the canceling function 2, and no canceling according to the quality of the communication path, And a demodulation device. A receiving device for receiving a signal transmitted from the transmitting device of claim 20, comprising: generating a duplicate of the signal of the traffic channel 2 multiplexed with a received signal from a symbol of the traffic channel 2 obtained by demodulating and determining the traffic channel 2, and receiving A cancellation function 1 for removing the signal component of the traffic channel 2 from the signal, and a copy of the traffic channel 2 multiplexed with the received signal from the data of the traffic channel 2 obtained by demodulating and decoding the traffic channel 2, and generating a received signal. The canceling function of the two canceling functions of the canceling function 2 which removes the signal component of the traffic channel 2 from the traffic signal, and selects one of the canceling function and the canceling function according to the quality of the communication path A receiver for demodulating channel 1. A modulation scheme using an orthogonal frequency division multiplexing (OFDM) technique, wherein the signal OFDM-modulated by the OFDM technique is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions thereof. OFCDM modulation) Traffic channel signal generating means for generating traffic channel signals by OFCDM modulation of the traffic channel data; Control channel signal generating means for generating a control channel signal from the control channel data using a signal that is not orthogonal to any of time, frequency, and code with respect to the traffic channel signal; Transmission signal generation means for generating a transmission signal by multiplexing the traffic channel signal and the control channel signal Transmitting apparatus comprising a. A modulation scheme using an orthogonal frequency division multiplexing (OFDM) technique, wherein the signal OFDM-modulated by the OFDM technique is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions thereof. OFCDM modulation) Traffic channel signal generating means for generating traffic channel signals by OFCDM modulation of the traffic channel data; Control channel signal generating means for generating a control channel signal by modulating the control channel data in an arbitrary manner; Switching means for switching the control channel signal and the traffic channel signal into a signal that is not orthogonal to any one of time, frequency, or code, and a signal orthogonal to any one of time, frequency, or code; Transmission signal generation means for generating a transmission signal by multiplexing the traffic channel signal and the control channel signal Transmitting apparatus comprising a. The method of claim 28, And said switching means switches to said non-orthogonal signal when the quality of the communication path is good, and switches to said orthogonal signal when the quality of the communication path is poor. The method of claim 28, And said switching means switches between said non-orthogonal signal and said orthogonal signal in accordance with the number of spreading codes currently being used in said traffic channel signal. The method according to any one of claims 27 to 30, And the control channel signal generated by the control channel signal generating means is the OFCDM modulated signal. The method of claim 27, The control channel signal generating means includes encoding means by a low rate block code, and means for arranging the codeword to be transmitted using a plurality of subcarriers of a single OFDM symbol. A receiving device for receiving a signal transmitted from the transmitting device according to any one of claims 27 to 32, Control channel signal processing means for demodulating control channel data from the control channel signal, traffic channel signal processing means for demodulating the traffic channel data by OFCDM demodulation of the traffic channel signal; Means for demodulating the control channel signal, generating a duplicate of the control channel signal multiplexed with the received signal from the demodulated signal, and means for removing a control channel signal component from the received signal; Receiving device comprising a. The method of claim 33, wherein The control channel canceler means generates a duplicate of the control channel signal multiplexed with the received signal from the control channel symbol obtained by the determination means for demodulating the control channel signal to determine a signal point, and from the received signal And after the signal component is removed, demodulation of the traffic channel signal. The method of claim 33, wherein The control channel canceler means generates a duplicate of the control channel signal multiplexed with the received signal from the control channel data obtained by demodulating the control channel signal and decoding it by the error correction code decoding means, and the control channel signal component from the received signal. And then demodulating the traffic channel signal. The method of claim 34 or 35, The control channel canceler means judges whether the traffic channel includes information forward to the local station from the control information obtained at the past or at the time, and receives when the traffic channel includes information forward to the local station. And demodulating the traffic channel signal after generating a duplicate of the control channel signal multiplexed on the signal and removing the control channel signal component from the received signal. The method of claim 33, wherein The control channel canceler means demodulates the control channel signal and generates a copy of the control channel from the control channel symbol obtained by determining the signal point by the determination means, and from the received signal, the control channel signal. Canceling (1) means for removing a component and a copy of the control channel multiplexed with a received signal from control channel data obtained by demodulating and decoding the control channel, and canceling the control channel signal component from the received signal ( 2) with means; And receiving means for canceling the traffic channel by selecting one of the canceling means, the canceling means, and the means for not canceling, depending on the quality of the communication path. The method of claim 33, wherein The control channel canceler means generates a duplicate of the control channel signal multiplexed with the received signal from a control channel symbol obtained by receiving a signal multiplexed with the traffic channel and the control channel and demodulating and determining the control channel. And a cancellation signal from the control channel data obtained by receiving the canceling (1) means for removing the control channel signal component from the received signal and a signal multiplexed with the traffic channel and the control channel, and demodulating and decoding the control channel. A canceling means of any one of the two canceling means of said canceling (2) means for generating a duplicate of said control channel multiplexed at and removing a control channel signal component from a received signal, And the demodulation of the traffic channel is performed by selecting whether or not to cancel the cancellation according to the quality of the communication path. A receiving device for receiving a signal transmitted from the transmitting device of any one of claims 28 to 30, Traffic channel signal processing means for demodulating the traffic channel data by OFCDM demodulation; Control channel signal processing means for performing demodulation processing of control channel data from the control channel signal; The control channel signal and the traffic channel signal may be demodulated in any one of a signal not orthogonal to any one of time, frequency, or code, and a signal orthogonal to any one of time, frequency, or code. Switching means for switching cords, Control channel canceller including copy means for generating a duplicate of the control channel signal multiplexed with the received signal from the received symbol or received data obtained by demodulating the control channel, and removing means for removing the control channel signal component from the received signal. With means, If the control channel is the orthogonal signal, the traffic channel is demodulated as it is, and if the control channel is the non-orthogonal signal, the control channel canceler cancels the control channel from the received signal after the control channel cancels. A demodulation device for demodulating a traffic channel. A receiving device for receiving a signal transmitted from the transmitting device of any one of claims 28 to 30, Traffic channel signal processing means for demodulating the traffic channel data by OFCDM demodulation; Control channel signal processing means for performing demodulation processing of control channel data from the control channel signal; The control channel signal and the traffic channel signal may be demodulated in any one of a signal not orthogonal to any one of time, frequency, or code, and a signal orthogonal to any one of time, frequency, or code. Switching means for switching cords, Control channel canceller including copy means for generating a duplicate of the control channel signal multiplexed with the received signal from the received symbol or received data obtained by demodulating the control channel, and removing means for removing the control channel signal component from the received signal. With means, The control channel canceler means controls the control signal from the received signal by the removal means, using the signal replicated by the copying means, depending on the quality of the communication path and whether the signal is orthogonal or non-orthogonal. A reception device, characterized in that it is determined whether or not to cancel channel cancellation, and selected to demodulate the traffic channel. A modulation scheme using an orthogonal frequency division multiplexing (OFDM) technique, wherein the signal OFDM-modulated by the OFDM technique is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions thereof. OFCDM modulation) Traffic channel signal 1 generating means for OFCDM modulating traffic channel data 1 to generate traffic channel signal 1; The traffic channel signal 2 from the traffic channel data 2, which is the slow traffic channel data, is compared to the traffic channel data 1 using a signal that is not orthogonal to any of time, frequency, and code with respect to the signal of the traffic channel 1; Means for generating a traffic channel signal 2 for generating a; Transmission signal generation means for generating a transmission signal by multiplexing the traffic channel signal 1 and the traffic channel signal 2 Transmitting apparatus comprising a. A modulation scheme using an orthogonal frequency division multiplexing (OFDM) technique, wherein the signal OFDM-modulated by the OFDM technique is a signal spread over a plurality of subcarriers, a plurality of OFDM symbols, or both regions thereof. OFCDM modulation) Traffic channel signal 1 generating means for OFCDM modulating traffic channel data 1 to generate traffic channel signal 1; Traffic channel 2 signal generating means for generating a signal of traffic channel 2 by modulating traffic channel data 2 in an arbitrary manner; Switching means for switching the signal of the traffic channel 2 and the signal of the traffic channel 1 into a signal that is not orthogonal to any one of time, frequency, or code, and a signal orthogonal to any one of time, frequency, or code; , Transmission signal generation means for generating a transmission signal by multiplexing the traffic channel signal 1 and the traffic channel signal 2 Transmitting apparatus comprising a. The method of claim 42, wherein And the switching means switches to the non-orthogonal signal when the quality of the communication path is good, and switches to the orthogonal signal when the quality of the communication path is poor. The method of claim 42, wherein And the switching means switches the non-orthogonal signal and the orthogonal signal according to the number of spreading codes currently being used in the signal of the traffic channel 1. The method according to any one of claims 41 to 44, And said traffic channel 2 signal generated by said traffic channel signal 2 generating means is said OFCDM modulated signal. The method of claim 41, wherein And said traffic channel signal generating means comprises encoding means by a low rate block code and means for arranging the code word to be transmitted using a plurality of subcarriers of a single OFDM symbol. A receiving device for receiving a signal transmitted from the transmitting device of any one of claims 41 to 44, Traffic channel 1 signal processing means for performing OFCDM demodulation on the traffic channel signal 1 to demodulate the traffic channel data 1; Traffic channel 2 signal processing means for performing demodulation processing of traffic channel data 2, which is slow traffic channel data, from the traffic channel signal 2, compared to the traffic channel data 1; Means for generating a replica of said traffic channel signal 2 multiplexed with a received signal and means for removing a component of said traffic channel signal 2 from said received signal; Receiving device comprising a. The method of claim 47, From the traffic channel data 2 obtained by demodulating the traffic channel 2 and decoding by the error correction code decoding means, a copy of the traffic channel signal 2 multiplexed to the received signal is generated by the traffic channel canceller means, and received. Receiving the signal component of said traffic channel 2 from the signal. The method of claim 47, Copying of the traffic channel signal 2 multiplexed to the received signal by the traffic channel canceller means from the symbol of the traffic channel 2 obtained by the determining means for demodulating the traffic channel signal 2 and determining the signal point. Generating and removing a component of the traffic channel signal 2 from the received signal. The method of claim 47, The traffic channel canceler means demodulates the traffic channel 2, and performs the duplication of the traffic channel signal 2 multiplexed to the received signal from the symbol of the traffic channel 2 obtained by the determination means to determine the signal point. The received signal from the canceling (1) means for generating and removing the components of the traffic channel signal 2 from the received signal, and the traffic channel data 2 obtained by demodulating the traffic channel 2 and decoding by the error correction code decoding means. Means for generating a replica of said traffic channel signal 2 multiplexed on and canceling said signal component of said traffic channel 2 from said received signal, And the demodulation of the traffic channel 1 is performed by selecting one of the canceling means, the canceling means, and the means for not canceling, depending on the quality of the communication path. The method of claim 47, The traffic channel canceller means generates a copy of the signal of the traffic channel 2 multiplexed with the received signal from the symbol of the traffic channel 2 obtained by demodulating and determining the traffic channel 2, and from the received signal, the traffic channel signal 2 Means for canceling (1) means for removing the component of?, And replicating of said traffic channel 2 multiplexed to said received signal from said traffic channel data 2 obtained by demodulating and decoding said traffic channel 2, and receiving said traffic channel signal from said received signal; Provided with only one of the two canceling means of the canceling means 2 for removing the component of 2, And the demodulation of the traffic channel 1 is performed by selecting whether or not to cancel the cancellation depending on the quality of the communication path. A receiving device for receiving a signal transmitted from the transmitting device according to any one of claims 42 to 44, Traffic channel 1 signal processing means for performing OFCDM demodulation on the traffic channel signal 1 to demodulate the traffic channel data 1; Traffic channel 2 signal processing means for demodulating traffic channel signal 2 to demodulate traffic channel data 2; Time so that the traffic channel signal 1 and the traffic channel signal 2 can be demodulated in any of a signal that is not orthogonal to any of time, frequency, or code, and a signal orthogonal to any one of time, frequency, or code; Switching means for switching frequencies or codes; Copying means for generating a duplicate of the traffic channel signal 2 multiplexed with the received signal from the received symbol or received data obtained by demodulating the traffic channel signal 2, and removing means for removing a component of the traffic channel signal 2 from the received signal; And a traffic channel 2 canceler means comprising: If the traffic channel signal 2 is the orthogonal signal, demodulation of the traffic channel data 1 is performed as it is. If the traffic channel signal 2 is the non-orthogonal signal, the signal copied by the traffic channel 2 canceler means is decoded. And demodulating the traffic channel data 1 after canceling the traffic channel signal 2 from the received signal. A receiving device for receiving a signal transmitted from the transmitting device according to any one of claims 42 to 44, Traffic channel 1 signal processing means for performing OFCDM demodulation on the traffic channel signal 1 to demodulate the traffic channel data 1; Traffic channel 2 signal processing means for demodulating traffic channel signal 2 to demodulate traffic channel data 2; Time so that the traffic channel signal 1 and the traffic channel signal 2 can be demodulated in any of a signal that is not orthogonal to any of time, frequency, or code, and a signal orthogonal to any one of time, frequency, or code; Switching means for switching frequencies or codes; Copying means for generating a duplicate of the traffic channel signal 2 multiplexed with the received signal from the received symbol or received data obtained by demodulating the traffic channel signal 2, and removing means for removing a component of the traffic channel signal 2 from the received signal; And a traffic channel 2 canceler means comprising: The traffic channel 2 canceler means uses the signal replicated by the copying means, depending on the quality of the communication path and whether the signal is orthogonal or non-orthogonal, from the received signal by the removing means. It is determined whether or not to cancel the traffic channel signal 2 or not, and the demodulation of the traffic channel data 1 is performed. The data communication system provided with the transmitter as described in any one of Claims 27-32, and the receiver as described in any one of Claims 33-38. A data communication system comprising the transmission device according to any one of claims 28 to 31 and the reception device according to claim 39 or 40. 52. The data communication system provided with the transmitter as described in any one of Claims 41-46, and the receiver as described in any one of Claims 47-51. A data communication system comprising the transmission device as claimed in any one of claims 42 to 45 and the reception device as claimed in claim 52 or 53.

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